Identifying Pharmacological Therapeutics for Aggressive Fibromatosis

Hong, Helen

30 May 2011

Aggressive fibromatosis is a fibroproliferative tumour that can occur as a sporadic lesion or a manifestation in FAP patients. Tumours are characterized by the stabilization of beta-catenin. Current therapies have yet to offer complete success for primary and recurrent tumours, and there remains a need for more effective therapeutic strategies. In this work, we demonstrate the anti-neoplastic and beta-catenin modulating capacities of Nefopam, a currently approved analgesic agent. We found that Nefopam was able to decrease cell viability and proliferation as well as total beta-catenin levels in human aggressive fibromatosis tumour cells in vitro. Furthermore, Nefopam reduced the number of tumours formed in the Apc+/Apc1638N aggressive fibromatosis mouse model. We also demonstrated that androgens contribute to the development of tumours and could also modulate beta-catenin levels as indicated in Testosterone-treated orchidectomized Apc+/Apc1638N mice. Together, this work suggests that Nefopam and androgen signaling-blocking agents are potential candidates to effectively manage aggressive fibromatosis.

aggressive fibromatosis

beta-catenin

wnt signaling

mouse model

0307

0992

Glypican-3 Stimulates the WNT Signaling Pathway by Facilitating/Stabilizing the Interaction of WNT LIigand and Frizzled Receptor

Martin, Tonya

12 January 2011

Glypican-3 (GPC3) belongs to a family of cell surface proteoglycans. GPC3 regulates the activity of several morphogens and growth factors that play critical roles during development. Disrupting the function of GPC3 leads to disease, including the overgrowth disease Simpson Golabi Behmel Syndrome (SGBS) and Cancer. Previous work has shown that GPC3 is over expressed in Hepatocellular Carcinoma (HCC), and that HCC proliferation is stimulated through GPC3 mediated activation of the Wnt signaling pathway. Glypicans are known to regulate Wnt signaling in a variety of model organisms including Drosophila and mouse. This work investigates the hypothesis that GPC3 stimulates Wnt signaling by facilitating/stabilizing the interaction between Wnt and its receptor Frizzled (Fzd). Consistent with this hypothesis, we found that GPC3 is able to bind both Wnt and Fzd. The binding of GPC3 to Fzd is mediated by the GPC3 glycosaminoglycan chains and by the cysteine rich domain of Fzd.

Glypican-3

Glypicans

Frizzled

Wnt pathway

Cell Signaling

0379

0307

Identifying Pharmacological Therapeutics for Aggressive Fibromatosis

Hong, Helen

30 May 2011

Aggressive fibromatosis is a fibroproliferative tumour that can occur as a sporadic lesion or a manifestation in FAP patients. Tumours are characterized by the stabilization of beta-catenin. Current therapies have yet to offer complete success for primary and recurrent tumours, and there remains a need for more effective therapeutic strategies. In this work, we demonstrate the anti-neoplastic and beta-catenin modulating capacities of Nefopam, a currently approved analgesic agent. We found that Nefopam was able to decrease cell viability and proliferation as well as total beta-catenin levels in human aggressive fibromatosis tumour cells in vitro. Furthermore, Nefopam reduced the number of tumours formed in the Apc+/Apc1638N aggressive fibromatosis mouse model. We also demonstrated that androgens contribute to the development of tumours and could also modulate beta-catenin levels as indicated in Testosterone-treated orchidectomized Apc+/Apc1638N mice. Together, this work suggests that Nefopam and androgen signaling-blocking agents are potential candidates to effectively manage aggressive fibromatosis.

aggressive fibromatosis

beta-catenin

wnt signaling

mouse model

0307

0992

The role of Hoxa2 gene in oligodendrocyte development

Nicolay, Danette Jacine

23 August 2007

Although numerous transcription factors (TFs) are expressed by oligodendrocytes (OGs), the role(s) of most of these TFs in oligodendrogenesis remains to be elucidated. One such TF is Hoxa2, which was recently shown to be expressed by O4-positive (+) pro-OGs. Hence, the main objectives of this thesis were to determine the expression profile and function(s) of Hoxa2 during OG development. Immunocytochemical analysis of primary mixed glial cultures demonstrated that Hoxa2 is expressed throughout oligodendrogenesis, diminishing only with the acquisition of a myelinating phenotype. Subsequently, immunohistochemical analysis suggested that Hoxa2 is expressed by migratory oligodendroglial cells in the embryonic spinal cord. However, double immunofluorescent analysis of Hoxa2 transgenic knockout mice showed that OG specification and early maturation proceed normally in the absence of Hoxa2 in the spinal cord. As Hoxa2 is one of 39 murine Hox genes, which exhibit extensive overlapping expression profiles in the spinal cord, we decided to examine the expression of an additional Hox TF, Hoxb4, during OG development. Immunocytochemical analysis of primary mixed glial cultures demonstrated that Hoxb4 is also expressed throughout OG development. Furthermore, comparison of the expression profiles of Hoxb4 and Olig2 suggested that Hoxb4 is expressed by oligodendroglial cells in the spinal cord. Hence, Hoxb4, as well as other Hox TFs could compensate for Hoxa2 in the spinal cord in its absence. As the anterior boundary of most Hox genes has been found to be in the hindbrain or spinal cord, we decided to look at the telencephalon which would be less likely to have compensatory mechanisms. Our results showed that similar to the spinal cord, Hoxa2 is expressed by oligodendroglial cells in the telencephalon. Subsequently, it was found that over-expressing Hoxa2 in CG4 cells, an oligodendroglial cell line derived from the perinatal rat cerebral cortex, impairs their differentiation. In an attempt to determine the mechanism by which it accomplishes this, we examined the expression of polysialylated neural cell adhesion molecule (PSA-NCAM), which has been implicated in this process. Contrary to our expectations, however, it was found that over-expressing Hoxa2 in CG4 cells results in significantly fewer PSA-NCAM+ cells. Hence, the results suggest that Hoxa2s effect on OG differentiation is independent of its effect on PSA-NCAM expression. The expression of Hox genes is enhanced by retinoic acid (RA), which, in turn, both inhibits, as well as promotes OG differentiation. Although the reason for these opposing roles is uncertain, examination of the experimental protocols utilized by different research groups reveals disparities in age, CNS region, as well as RA concentration. As a result, RAs effect on oligodendrogenesis could be stage- and/or concentration-dependent. In order to determine which of these factors could impact RAs effect on OG differentiation we treated CG4 cells with two different concentrations of RA at two distinct time points. The results showed that both factors (concentration and time/stage) can impact RAs effect on CG4 cell differentiation. In an attempt to determine the mechanism by which it accomplishes this, we examined the expression of PSA-NCAM. Contrary to our expectations, the results suggest that RAs effect on CG4 differentiation is independent of its effect on PSA-NCAM expression. The results of this thesis suggest that Hoxa2 and RA could play multiple roles in OG development. Although these roles appear to be similar, further research will be needed to determine whether Hoxa2 acts a downstream effector in the RA signaling pathway in oligodendroglial cells.

retinoic acid

signaling pathways

differentiation

specification

transcription factors

Modeling of metabolic insulin signaling in adipocytes

Ulfhielm, Erik

January 2006

Active insulin receptors (IR) phosphorylate insulin receptor substrate (IRS), but it is not clear whether IRS is phosphorylated mainly by IR at the plasma membrane or by internalized IR in the cytosol. In this thesis, structural identifiability analysis and parameter sensitivity analysis is performed for models of the first steps in the metabolic insulin signaling pathway. In particular, the identifiability of the kinetic parameters governing IRS phosphorylation are investigated. Given measurements of the relative increase in phosphorylation degree of IR and IRS, the structural identifiability analysis revealed that the parameters governing IRS phosphorylation are non-identifiable, but their ratio is identifiable. This is sufficient to study whether phosphorylation of IRS proceeds more rapidly by IR at the plasma membrane or by internalized IR in the cytosol. In the examined model structure, internalization of insulin receptors is shown to be necessary to reproduce the experimental data. Sensitivity analysis of the parameters governing IRS phosphorylation showed that many parameters need to be known in order to obtain ``practical identifiability'' of the interesting parameters.

identifiability

insulin signaling

systems biology

Automatic control

Reglerteknik

Regulation of Metalloproteinase-dependent Ectodomain Shedding in Cytokine Biology and Inflammation

Murthy, Aditya

11 January 2012

In 1962, Gross and Lapiere described collagenolytic activity in the degradation of tadpole tails during amphibian metamorphosis. This activity was later attributed to a collagenase enzyme belonging to the matrix metalloproteinase family. Over the past 49 years, steady growth in the field of metalloproteinase biology has uncovered that degradation of extracellular matrix components represents only a fraction of the functions performed by these enzymes. The regulatory roles of these enzymes in numerous aspects of mammalian biology remains poorly understood. This thesis investigates the metalloproteinase ADAM17 and its natural inhibitor TIMP3 in acute and chronic inflammation. My work describes the generation of new murine experimental systems of compartmentalized ADAM17 or TIMP3 deficiency and their applications in acute liver inflammation (i.e. fulminant hepatitis and T-cell mediated autoimmune hepatitis) and atopic dermatitis. Loss of Timp3 protected mice against fulminant hepatic failure caused by activation of the death receptor Fas. We determined that TIMP3 simultaneously promotes pro-apoptotic signaling through TNFR1 while suppressing anti-apoptotic EGFR activation in the liver. Mechanistically, we identified that ADAM17 is critical in shedding TNFR1 and EGFR ligands (e.g. Amphiregulin, HB-EGF, TGF) and extended this finding to clinically relevant drug-induced hepatitis. Adult TIMP3 deficient mice also exhibited spontaneous accumulation of CD4+ T cells in the liver. Consequently, polyclonal T cell activation with the lectin Concanavalin A (con A) in a model of autoimmune hepatitis resulted in accelerated liver injury. We identified that this immunopathology relied on TNF bioavailability as mice lacking both Timp3 and Tnf were resistant to con A. Using bone marrow chimeras we established that non-hematopoietic tissues were the physiologically relevant source of TIMP3 in vivo, thereby highlighting an immunosuppressive role for this stromal metalloproteinase inhibitor in cellular immunity. Finally, we investigated epithelial:immune crosstalk in the epidermis by generating tissue-specific ADAM17 deficiency in basal keratinocytes. These mice developed spontaneous inflammatory skin disease that was physiologically consistent with atopic dermatitis. Focused investigation of keratinocyte-specific signaling deregulated by ADAM17 deficiency revealed its requirement for tonic Notch activation, which in turn antagonized transcriptional activity of AP-1 transcription factors on the promoters of epithelial cytokines TSLP and G-CSF. In summary, these works identify cellular mechanisms governing cytokine-mediated communication between epithelial and immune cells to modulate inflammation. The findings that TIMP3 and ADAM17 act as regulators of key inflammatory, proliferative and developmental pathways provide impetus to expand our understanding of this important family of enzymes in mammalian signal transduction.

Immunology

Genetics

Metalloproteinase

Cytokine

Inflammation

Signaling

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0369

0982

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Exploring DNA Damage Induced Foci and their Role in Coordinating the DNA Damage Response

Yeung, ManTek

31 August 2012

DNA damage represents a major challenge to the faithful replication and transmission of genetic information from one generation to the next. Cells utilize a highly integrated network of pathways to detect and accurately repair DNA damage. Mutations arise when DNA damage persists undetected, unrepaired, or repaired improperly. Mutations are a driving force of carcinogenesis and therefore many of the DNA damage surveillance and repair mechanisms guard against the transformation of normal cells into cancer cells. Central to the detection and repair of DNA damage is the relocalization of DNA damage surveillance proteins to DNA damage where they assemble into subnuclear foci and are capable to producing a signal that the cell interprets to induce cellular modifications such as cycle arrest and DNA repair which are important DNA damage tolerance. In this work, I describe my quest to understand the mechanisms underlying the assembly, maintenance, and disassembly of these DNA damage-induced foci and how they affect DNA damage signaling in Saccharomyces cerevisiae. First, I describe phenotypic characterization of a novel mutation that impairs assembly of the 9-1-1 checkpoint clamp complex into foci. Second, I describe my work to further understand the roles of the histone phosphatase Pph3 and phosphorylated histone H2A in modulating DNA damage signaling. Third, I include my work to uncover the possible mechanism by which the helicase Srs2 works to enable termination of DNA damage signaling. In summary, this thesis documents my efforts to understand the cellular and molecular nature of DNA damage signaling and how signaling is turned off in coordination with DNA damage repair.

DNA damage

signaling

foci

DNA repair

checkpoint

recovery

0307

0379

Regulation of Cell Differentiation in Dictyostelium: The Role of Calcium and Calmodulin

Poloz, Yekaterina

31 August 2012

Dictyostelium is a well established model for the study of differentiation and morphogenesis. It has previously been shown that Ca2+ and its primary sensor calmodulin (CaM) have roles in cell differentiation and morphogenesis in Dictyostelium and higher eukaryotes. Here I further elucidated the role of Ca2+ and CaM in cell differentiation in Dictyostelium. No previous work existed on the regulation of CaM-binding proteins (CaMBPs) or their binding partners by developmental morphogens. First, I gained insight into the developmental role of nucleomorphin (NumA1), a novel CaMBP, as well as its binding partners Ca2+-binding protein 4a (CBP4a) and puromycin-sensitive aminopeptidase A (PsaA). I showed that NumA1 and CBP4a expression is co-regulated by differentiation-inducing factor-1 (DIF-1), a stalk cell morphogen. Both proteins likely have a role in prestalk-O cell differentiation. On the other hand, I showed that PsaA expression is regulated by cAMP and PsaA regulates spore cell differentiation. Thus, NumA1 likely differentially regulates stalk and spore cell differentiation by interacting with CBP4a and PsaA, respectively. I also used Dictyostelium as a model to gain insight into the mechanism of action of colchicine, a microtubule disrupting agent that has been shown to affect differentiation and morphogenesis in many organisms. I identified that colchicine affects cell motility, disrupts morphogenesis, inhibits spore cell differentiation and induces stalk cell differentiation through a Ca2+ and CaM-dependent signal transduction pathway. It specifically induced differentiation of ecmB expressing stalk cells, independent of DIF-1 production. Lastly, I analyzed for the first time the role of Ca2+ and CaM in ecmB expression in vivo. I showed that Ca2+ and CaM regulate ecmB expression in intact and regenerating slugs and that Ca2+ and CaM also regulate cell differentiation, motility and slug shape. In conclusion, Ca2+ and CaM play integral roles in cell motility, cell differentiation and morphogenesis in Dictyostelium.

Dictyostelium

cell differentiation

calcium

calmodulin

signaling

morphogenesis

0379

0307

Functions of Lunatic and Manic Fringe in Regulating the Strength and Specificity of Notch Receptor-ligand Interactions during Hematopoiesis

Yuan, Julie S.

26 February 2009

Notch signals are required to promote T lineage commitment and development and suppress alternative cell fates in the thymus. Although the Notch activating ligand(s) in the thymus is(are) not known, studies have shown that hematopoietic progenitors are sensitive to Delta-like (DL), but not Jagged (Jag)-type ligands. In Chapter 3, I show that DL-expressing bone marrow stromal cell lines exhibit Notch ligand-independent functional heterogeneity in their capacity to support T cell development in vitro. These findings thus suggest the existence of stromal cell-derived signals that work with Notch to support T cell development. In Chapters 4 and 5, I investigated the ability of Fringe proteins to modulate Notch ligand-receptor interactions and the developmental consequences of these interactions for hematopoetic progenitors. Fringe proteins are glycosyl-transferases that enhance Notch activation by DL ligands and inhibit Notch activation by Jag ligands. In Chapter 4 I show that Lunatic Fringe (Lfng) enhances the strength of DL-mediated Notch activation to drive proliferation and expansion of early thymocytes and that DL4 and DL1 display different potencies to induce Notch-dependent outcomes. In Chapter 5, I demonstrate for the first time in a mammalian system that Lfng and Manic Fringe (Mfng) co-operate to enhance DL-Notch interactions and inhibit Jag-Notch interactions in hematopoietic stem cells. Thus, Lfng and Mfng function together to induce T cell development and inhibit B cell, myeloid and NK cell development. Collectively, these data highlight the importance of Fringe proteins in modulating the strength and specificity of Notch signaling levels during hematopoieisis.

Immunology

hematopoiesis

T cell development

Notch signaling

lymphocyte development

0982

The in vivo Function of Nuclear Receptors During Drosophila Development

Necakov, Aleksandar Sasha

22 February 2011

Nuclear receptors (NR’s) comprise a large, ancient, superfamily of eukaryotic transcription factors that govern a wide range of metabolic, homeostatic, and developmental pathways, and which have been implicated in disease states including cancer, inflammation, and diabetes. The ability of NRs to activate or repress gene transcription is modulated through direct binding of small lipophilic ligands which induce conformational changes in their cognate receptor. These changes are structural in nature and lead to the recruitment of coactivator or corepressor complexes, ultimately regulating the expression of target genes to whose response elements NRs are bound. In Drosophila 18 NRs have been identified which have representative members belonging to each of the six major NR subfamilies, and which show a high degree of homology to their vertebrate counterparts. This fact, in addition to the power and ease of genetic manipulation, make Drosophila an excellent model system in which to study NR function. When I began my project, 17 of the 18 NRs in Drosophila were ‘orphan’ receptors for which no cognate ligand had been identified. As a first step in an effort to identify potential ligands for these 17 receptors I first set out to determine how, where and when nuclear receptors are regulated by small chemical ligands and/or their protein partners. In order to do so I contributed to developing a ‘ligand sensor’ system to visualize spatial activity patterns for each of the 18 Drosophila nuclear receptors in live, developing animals. This system is based upon transgenic lines that express the ligand binding domain of each Drosophila NR fused to the DNA-binding domain of yeast GAL4. When combined with a GAL4-responsive reporter gene, these fusion proteins show tissue- and stage-specific patterns of activation. Analysis using this system has revealed the stage and tissue specificity of NR activation for each of the fly NRs. The amnioserosa, yolk, midgut and fat body, which play major roles in lipid storage, metabolism and developmental timing, were identified as frequent sites of nuclear receptor activity. Dynamic changes in activation that are indicative of sweeping changes in ligand and/or co-factor production are also a prominent feature that has been revealed using this approach. In addition, I went on to characterize the ligand regulated function of a single Drosophila nuclear receptor, Ecdysone inducible protein 75 (E75). Previous work from our lab has demonstrated that E75 binds to heme, and that its function as a transcriptional repressor is regulated in vitro by binding of the small diatomic gases nitric oxide (NO) and carbon monoxide (CO) to its heme moiety. In an effort to validate and to further understand the in vivo relevance of E75 regulation by NO I used gain and loss of function transgenes, as well as tissues manipulated in culture to show that NO acts directly on the Drosophila nuclear receptor E75, reversing its ability to block the activity of its heterodimer partner Drosophila Hormone Receptor 3 (DHR3). By specifically focusing on the Drosophila larval ring gland, the principal endocrine organ responsible for the production of the metamorphosis-inducing hormone, ecdysone, I have shown that failure to produce NO and to inactivate E75 results in failure to recognize the signals that normally trigger metamorphosis.

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