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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Effect of nitric oxide and inflammatory mediators on axonal transport / Effect of nitric oxide and inflammatory mediators on axonal transport / Effect of nitric oxide and inflammatory mediators on axonal transport / Effect of nitric oxide and inflammatory mediators on axonal transport

Stagi, Massimiliano 01 November 2005 (has links)
No description available.
2

Mechanisms of High Glucose-induced Decrease in β-cell Function

Tang, Christine 23 February 2011 (has links)
Chronic hyperglycemia, a hallmark of type 2 diabetes, can decrease β-cell function and mass (β-cell glucotoxicity); however, the mechanisms are incompletely understood. The objective was to examine the mechanisms of β-cell glucotoxicity using in vivo and ex vivo models. The hypothesis is that oxidative stress plays a causal role in high glucose-induced β-cell dysfunction in vivo via pathways that involve endoplasmic reticulum (ER) stress and JNK. The model of β-cell glucotoxicity was achieved by prolonged i.v. glucose infusion (to achieve hyperglycemia). In Study 1, 48h glucose infusion increased total and mitochondrial superoxide levels in islets, and impaired β-cell function in vivo and ex vivo. Co-infusion of the superoxide dismutase mimetic Tempol decreased total and mitochondrial superoxide, and prevented high glucose-induced β-cell dysfunction in vivo and ex vivo. These results suggest that increased superoxide generation plays a role in β-cell glucotoxicity. In Study 2, 48h glucose infusion increased activation of the unfolded protein response (XBP-1 mRNA splicing and phospho-eIF2α levels). This was partially prevented by Tempol. Co-infusion of the chemical chaperone 4-phenylbutyrate with glucose decreased spliced XBP-1 levels, and prevented high glucose-induced β-cell dysfunction in vivo and ex vivo. Co-infusion of 4-phenylbutyrate also decreased total and mitochondrial superoxide induced by high glucose. These results suggest that 1) ER stress plays a causal role in high glucose-induced β-cell dysfunction, and 2) there is a link between oxidative stress and ER stress in high glucose-induced β-cell dysfunction in vivo. In Study 3, JNK inhibition using the inhibitor SP600125 in rats or JNK-1 null mice prevented high glucose-induced β-cell dysfunction ex vivo and in vivo. SP600125 prevented high-glucose-induced β-cell dysfunction without decreasing total and mitochondrial superoxide levels. Both Tempol and 4-phenylbutyrate prevented JNK activation induced by high glucose. These results suggest a role of JNK activation in high glucose-induced β-cell dysfunction downstream of increased superoxide generation and ER stress in vivo. Together, the results suggest that 1) oxidative stress, ER stress and JNK activation are causally involved in β-cell glucotoxicity, and 2) High glucose-induced oxidative stress and ER stress are linked, and both impair β-cell dysfunction via JNK activation in vivo.
3

Mechanisms of High Glucose-induced Decrease in β-cell Function

Tang, Christine 23 February 2011 (has links)
Chronic hyperglycemia, a hallmark of type 2 diabetes, can decrease β-cell function and mass (β-cell glucotoxicity); however, the mechanisms are incompletely understood. The objective was to examine the mechanisms of β-cell glucotoxicity using in vivo and ex vivo models. The hypothesis is that oxidative stress plays a causal role in high glucose-induced β-cell dysfunction in vivo via pathways that involve endoplasmic reticulum (ER) stress and JNK. The model of β-cell glucotoxicity was achieved by prolonged i.v. glucose infusion (to achieve hyperglycemia). In Study 1, 48h glucose infusion increased total and mitochondrial superoxide levels in islets, and impaired β-cell function in vivo and ex vivo. Co-infusion of the superoxide dismutase mimetic Tempol decreased total and mitochondrial superoxide, and prevented high glucose-induced β-cell dysfunction in vivo and ex vivo. These results suggest that increased superoxide generation plays a role in β-cell glucotoxicity. In Study 2, 48h glucose infusion increased activation of the unfolded protein response (XBP-1 mRNA splicing and phospho-eIF2α levels). This was partially prevented by Tempol. Co-infusion of the chemical chaperone 4-phenylbutyrate with glucose decreased spliced XBP-1 levels, and prevented high glucose-induced β-cell dysfunction in vivo and ex vivo. Co-infusion of 4-phenylbutyrate also decreased total and mitochondrial superoxide induced by high glucose. These results suggest that 1) ER stress plays a causal role in high glucose-induced β-cell dysfunction, and 2) there is a link between oxidative stress and ER stress in high glucose-induced β-cell dysfunction in vivo. In Study 3, JNK inhibition using the inhibitor SP600125 in rats or JNK-1 null mice prevented high glucose-induced β-cell dysfunction ex vivo and in vivo. SP600125 prevented high-glucose-induced β-cell dysfunction without decreasing total and mitochondrial superoxide levels. Both Tempol and 4-phenylbutyrate prevented JNK activation induced by high glucose. These results suggest a role of JNK activation in high glucose-induced β-cell dysfunction downstream of increased superoxide generation and ER stress in vivo. Together, the results suggest that 1) oxidative stress, ER stress and JNK activation are causally involved in β-cell glucotoxicity, and 2) High glucose-induced oxidative stress and ER stress are linked, and both impair β-cell dysfunction via JNK activation in vivo.
4

Analysis of Protein Adduction Kinetics and the Effects of Protein Adduction on C-Jun N-Terminal Kinase Signaling

Orton, Christopher R. January 2006 (has links)
Defining the mechanics and consequences of protein adduction is crucial to understanding the toxicity of reactive electrophiles. Application of tandem mass spectrometry and data analysis algorithms enables detection and mapping of chemical adducts at the level of amino acid sequence. Nevertheless, detection of adducts does not indicate relative reactivity of different sites. In this dissertation I describe a method to measure the kinetics of competing adduction reactions at different sites on the same protein using quantitative mass spectrometry. Adducts are formed by electrophiles at Cys-14 and Cys-47 on the metabolic enzyme glutathione-S-transferase P1-1 and accompanied by a loss of enzymatic activity. Relative quantitation of protein adducts was done by tagging N-termini of peptide digests with isotopically labeled phenyl isocyanate and tracking the ratio of light-tagged peptide adducts to heavy-tagged reference samples. This method was used to measure rate constants for adduction at both positions with two different model electrophiles, IAB and BMCC. The results indicate that Cys-47 was approximately 2-3-fold more reactive toward both electrophiles than was Cys-14. This result was consistent with the relative reactivity of these electrophiles in a complex proteome system. Quantitative analyses of protein modifications provide a means of determining the reactivity and selectivity of damaging protein modifications in chemical toxicity.Another area of study explored in this dissertation is looking at the effects of protein alkylation on activating cellular signaling pathways, specifically the JNK signaling pathway. Protein adduction has been shown to be selective between different alkylating agents. It would then be reasonable to think this selectivity of adduction translates to selectivity of downstream consequences or cellular events directly tied to specific adductions. My work will show how treatment of HEK293 cells with either IAB or BMCC leads to differences in activation of JNK signaling. In addition, I've been able to show a difference in selectivity of a number of adducted targets by each alkylating agent, which are directly involved in regulation of the JNK signaling pathway. These studies illustrate not only the significance of protein adduction, but the importance for continual research to better understand their behavior in living systems.
5

The role of c-jun N-terminal kinase (JNK) in human T cell function.

Melino, Michelle January 2009 (has links)
T cells are involved in cellular pathways which enable the immune system to protect us against infection and cancer. However, the same mechanisms also allow T cells to generate chronic inflammatory conditions, including autoimmunity and allergy. Thus a concerted effort has been made to try to understand how the immune system functions in order to inhibit responses which may have harmful effects on tissues and organs. There is a continued search for new immunosuppressants which can only be accomplished through a better understanding of the pathways that regulate T cell function. This includes the intracellular signalling pathways which modulate T cell proliferation and cytokine production. While the Mitogen-Activated Protein Kinases (MAPK), extracellular signal-regulated protein kinases (ERK) and p38 have received attention, the role of the stress-activated protein kinases or c-jun N-terminal kinases (JNK) remains controversial. To overcome some of the limitations in studying the role of JNK, a new approach was taken in this thesis. The investigations used recently described peptides (TAT-JIP[subscript]153-163 and TAT-JIP[subscript]153-172) derived from the scaffold protein, JIP-1, which have previously been demonstrated to act as JNK pathway inhibitors. The research characterised the specificity of these inhibitors to enable the appropriate interpretation of data. Using these inhibitors, we were able to show that JNK regulated human T cell proliferation and cytokine production in T cell responses induced independently of TCR ligation (PHAPMA) or via the TCR (anti-CD3-anti-CD28 antibodies, Mixed Lymphocyte Reaction (MLR), Tetanus Toxoid and Der p 2). The data demonstrated that JNK primarily regulated the Th1 cytokine patterns (IFNγ, IL2 and LT) with minimal effect on Th2 cytokine production (IL4, IL10) in response to all stimulatory models. However, while the JNK signalling pathway promoted T cell proliferation and cytokine production in response to PHA-PMA, the pathway depressed these responses following stimulation with anti-CD3-anti-CD28 antibodies and Tetanus Toxoid. Thus activation of JNK with microbial pathogens such as Pseudomonas aeruginosa (PA), which non-specifically activate T cells, may promote lymphocyte proliferation and the release of Th1 cytokines, such as IFNγ. In contrast, JNK activation resulting from engagement of the T cell receptor (TCR) (i.e. Tetanus Toxoid), down-regulates Th1 cytokine production. Therefore, it is likely that the JNK signalling pathway may dampen the development of chronic inflammatory conditions resulting from infection with intracellular parasites and autoimmune diseases. In contrast to Tetanus Toxoid, responses to the recombinant house dust mite allergen, Dermatophagoides pteronyssinus (Der p 2) were promoted by JNK, leading to an increase in Th1 cytokine production. Thus the results suggest that the use of JNK inhibitors could exacerbate both inflammatory conditions (autoimmunity and allergy) and this may also apply to p38 but not the ERK signalling pathway. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1374669 / Thesis (Ph.D.) - University of Adelaide, School of Molecular and Biomedical Science, 2009
6

Investigating the role of the c-Jun NH2-terminal kinase pathway in ErbB2-driven breast cancer and macrophage polarization

Yu, Lola 09 September 2020 (has links)
Breast cancer is the second most common malignancy in the world, accounting for over 1.7 million new diagnoses and an estimated 500,000 deaths per year (1). Overexpression of the receptor tyrosine kinase ErbB2, also known as Her2 or Neu, occurs in over 30% of breast cancers and correlates with metastasis, poor prognosis, and decreased survival (1, 2). Although therapeutics targeting ErbB2 show clinical efficacy, many patients display no initial response or develop drug resistance over time (2). A deeper understanding of the molecular basis of ErbB2-driven tumorigenesis is thus required for the development of improved therapeutic strategies. In vitro experiments suggest that activation of the c-Jun NH2-terminal kinase (JNK) pathway, a mitogen-activated protein kinase pathway, promotes proliferation, cellular invasion, and stem cell expansion in ErbB2-driven breast cancer (3, 4). Furthermore, unpublished data from our lab using mammary epithelial cells expressing activated ErbB2 show that JNK is required for acinus formation in in vitro 3D cultures. In contrast to these studies showing a tumorigenic role for the JNK pathway, other data from our lab show that JNK loss results in accelerated breast tumor growth, suggesting a tumor suppressive role (5, 6). However, these studies were performed in p53 knockout mice with or without a Kras mutation, where the latter required extensive aging and genomic instability to occur before differences in tumor growth were observable. To date, limited in vivo studies exist to confirm the role of JNK in more biologically relevant breast tumor models, such as in ErbB2-mediated cancer, which accounts for over 30% of all human breast cancers. In addition, the molecular mechanisms by which JNK signaling promotes ErbB2-driven tumorigenesis remains poorly understood. To address the discrepancy in JNK function between the in vitro ErbB2-driven breast cancer data and the in vivo p53 knockout tumor data, I began the development of an in vivo murine model to confirm the role of JNK in ErbB2-driven breast cancer. This mouse model will also allow us to test a potential mechanism by which JNK regulates tumorigenesis. Studies show that ErbB2-mediated secretion of the inflammatory cytokine IL6 promotes transformation and tumor growth by activation of the STAT3 transcription factor, triggering an IL6/STAT3 autocrine signaling loop (7,8). A major regulator of Il6 gene expression includes activator protein 1 (AP-1), a transcription factor composed of downstream JNK targets in the Jun protein family (9). In vitro experiments using ErbB2-overexpressing mammary epithelial cell lines show that chemical inhibition of JNK suppresses secreted IL6 protein levels, supporting a role for the JNK pathway in IL6 regulation (7). Thus, I hypothesize that JNK drives ErbB2-driven breast cancer by promoting IL6-mediated tumor progression. Addressing this will increase our understanding of the role of JNK in ErbB2-driven breast cancer and reveal a potentially new mechanism by which JNK functions in tumor progression. Additionally, I began the development of a mouse model that will allow us to investigate the role of JNK in macrophage polarization as an alternative mechanism by which JNK regulates ErbB2-driven breast cancer. In addition to promoting STAT3-dependent tumor growth, IL6 can indirectly drive tumorigenesis by promoting expression of the IL4 receptor in macrophages, triggering STAT6-mediated macrophage polarization towards the pro-tumorigenic M2 phenotype (10, 11). Unlike classically activated M1 macrophages, which promote inflammation and anti-tumor immunity, alternatively activated M2 macrophages function in immunosuppression and metastasis and correlate with advanced stages of breast cancer (12, 13). Further evidence supporting a role for the JNK pathway in macrophage polarization includes a recent study suggesting that JunB, a downstream JNK target and component of the AP-1 complex, plays a crucial role in the induction of M2 macrophage polarization in human alveolar macrophages (13). I hypothesize that activation of the JNK signaling pathway induces IL6-dependent macrophage polarization towards the pro-tumorigenic M2 phenotype. Addressing this hypothesis will determine for the first time whether JNK functions in regulating macrophage polarization within the tumor microenvironment, offering a potentially new mechanism by which JNK can promote ErbB2-driven breast cancer. Determining the role of JNK in ErbB2-mediated breast cancer will have direct therapeutic relevance, as targeting JNK has the potential to inhibit ErbB2-driven breast cancer and other IL6-mediated diseases. Investigating the underlying mechanisms by which JNK functions in ErbB2-positive breast cancer can also offer new molecular targets and further contribute to effective drug design.
7

Oxidative stress induced C-Jun N-terminal Kinase (JNK) activation in tendon cells upregulates MMP1 mRNA and protein expression

Wang, Fang, St George Clinical school, UNSW January 2006 (has links)
To explore the potential mechanisms of tendon degeneration, we investigated the role of c-Jun N-terminal Kinase (JNK) activation and the regulation of matrix metalloproteinase 1 (MMP1) in tendon matrix degradation under oxidative stress. JNK and MMP1 activity in samples from normal and ruptured human supraspinatus tendons were evaluated by immunohistochemistry. Real-time quantitative PCR was utilized to evaluate MMP1 mRNA expression and western blotting for MMP1 and JNK protein detection. JNK activation and increased MMP1 activity were found in the torn human supraspinatus tendon tissue, as well as in human tendon cells under in vitro oxidative stress. Inhibition of JNK prevented MMP1 over-expression in oxidative stressed human tendon cells. Results from the current study indicated that stress activated JNK plays an important role in tendon matrix degradation, possibly through upregulating of MMP1.
8

T-bet-Mediated Tim-3 Expression Dampens Monocyte Function During Chronic Hepatitis C Virus Infection

Yi, Wenjing, Zhang, Peixin, Liang, Yan, Zhou, Yun, Shen, Huanjun, Fan, Chao, Moorman, Jonathan P., Yao, Zhi, Jia, Zhansheng, Zhang, Ying 01 March 2017 (has links)
Hepatitis C virus (HCV) induces a high rate of chronic infection via dysregulation of host immunity. We have previously shown that T-cell immunoglobulin and mucin domain protein-3 (Tim-3) is up-regulated on monocyte/macrophages (M/Mφ) during chronic HCV infection; little is known, however, about the transcription factor that controls its expression in these cells. In this study, we investigated the role of transcription factor, T-box expressed in T cells (T-bet), in Tim-3 expression in M/Mφ in the setting of HCV infection. We demonstrate that T-bet is constitutively expressed in resting CD14+ M/Mφ in the peripheral blood. M/Mφ from chronically HCV-infected individuals exhibit a significant increase in T-bet expression that positively correlates with an increased level of Tim-3 expression. Up-regulation of T-bet is also observed in CD14+ M/Mφ incubated with HCV+ Huh7.5 cells, as well as in primary M/Mφ or monocytic THP-1 cells exposed to HCV core protein in vitro, which is reversible by blocking HCV core/gC1qR interactions. Moreover, the HCV core-induced up-regulation of T-bet and Tim-3 expression in M/Mφ can be abrogated by incubating the cells with SP600125 – an inhibitor for the c-Jun N-terminal kinase (JNK) signalling pathway. Importantly, silencing T-bet gene expression decreases Tim-3 expression and enhances interleukin-12 secretion as well as signal transducer and activator of transcription 1 phosphorylation. These data suggest that T-bet, induced by the HCV core/gC1qR interaction, enhances Tim-3 expression via the JNK pathway, leading to dampened M/Mφ function during HCV infection. These findings reveal a novel mechanism for Tim-3 regulation via T-bet during HCV infection, providing new targets to combat this global epidemic viral disease.
9

SUMO-1 conjugation blocks beta-amyloid-induced astrocyte reactivity.

Hoppe, J.B., Rattray, Marcus, Tu, H., Salbego, C.G., Cimarosti, H. 06 1900 (has links)
No / Astrocyte reactivity is implicated in the neuronal loss underlying Alzheimer's disease. Curcumin has been shown to reduce astrocyte reactivity, though the exact pathways underlying these effects are incompletely understood. Here we investigated the role of the small ubiquitin-like modifier (SUMO) conjugation in mediating this effect of curcumin. In beta-amyloid (Aβ)-treated astrocytes, morphological changes and increased glial fibrillary acidic protein (GFAP) confirmed reactivity, which was accompanied by c-jun N-terminal kinase activation. Moreover, the levels of SUMO-1 conjugated proteins, as well as the conjugating enzyme, Ubc9, were decreased, with concomitant treatment with curcumin preventing these effects. Increasing SUMOylation in astrocytes, by over-expression of constitutively active SUMO-1, but not its inactive mutant, abrogated Aβ-induced increase in GFAP, suggesting astrocytes require SUMO-1 conjugation to remain non-reactive.
10

The role of mitochondria in regulating MAPK signalling pathways during oxidative stress

Pang, Wei Wei January 2006 (has links)
[Truncated abstract] Reactive oxygen species (ROS) have been implicated to play a major role in many pathological conditions including heart attack and stroke. Their ability to modulate the extracellular signal-regulated protein kinase (ERK) and c-Jun Nterminal kinase (JNK) signalling pathways, thereby influencing cellular response has been well-documented. Recent studies implicate a central role for mitochondria in ERK and JNK activation by ROS although the mechanisms remained unresolved. Using Jurkat T-lymphocyte as a cell model, this study demonstrated increased mitochondrial ROS production as a result of decreased mitochondrial complex activities mediated by hydrogen peroxide treatment. This is the first study to show that mitochondria are not essential for activating ERKs, however damaged mitochondria producing ROS can be expected to cause sustained ERK activation . . . This study revealed that JNK and its upstream kinases MKK4, MKK7 and ASK1 are associated with the mitochondria. Furthermore, findings from this study imply that JNK resides in the mitochondrial matrix. This study is the first to demonstrate that mitochondrial JNK can be activated in a cell-free environment by signals originating from the mitochondria. Experimental work using isolated mitochondria demonstrated that mitochondrial JNK can be activated by ROS generated from the mitochondria themselves. Flavin-containing proteins appear to be the main sources of mitochondrial-ROS which signal through redoxsensitive proteins to activate mitochondrial JNK.

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