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A Study On The Roles Of The Ras Activation Pathway During Interferonγ Mediated Functional Responses And Acetaminophen-induced Liver Injury In MiceSaha, Banishree 05 1900 (has links)
Interferons (IFNs) perform a wide range of biological activities: anti-microbial, anti-proliferative, immunomodulatory etc. The IFN family includes three main classes: Type I, Type II and the recently identified Type III. The two main members of Type I class are IFNα and IFNβ, which are well known for their anti-viral roles. IFNλ, a member of the Type III class of IFNs, also exhibits antiviral activity. IFNγ, also known as immune IFN, is a Type II IFN which is secreted, primarily, by activated T cells, NK cells and macrophages. IFNγ is a potent immunomodulator which plays important roles in host defense. The diverse functions of this cytokine are demonstrated in Ifnγ-/- mice which display increased sensitivity to several pathogens, high incidences of tumors, reduced inflammatory response etc.
IFNγ binds to its cognate receptors, which consist of two subunits, IFNγ receptor (IFNGR) 1 and IFNGR2. IFNγ mediates its multifarious biological actions by activating the Janus activated kinase (Jak)-Signal transducer and activator of transcription (Stat) 1 signaling pathway. Jaks belong to a family of non-receptor protein tyrosine kinases and phosphorylate the IFNγ receptor and the transcriptional co-activator, Stat. IFNGR1, the larger subunit, is required for ligand binding and its carboxyl terminus is involved in binding to Jak1, which in turn phosphorylates Stat1. The smaller subunit, IFNGR2, is required for signaling and contains the Jak2 binding site. After binding of IFNγ to its receptor, a series of phosphorylation events occur, resulting in Stat1 phosphorylation and homodimerization of Stat1 to form the gamma activating factor (GAF). These activated molecules translocate to the nucleus and bind to gamma activating sequence (GAS) present in the promoters of several IFNγ-modulated genes. Thus, the cellular responses mediated by IFNγ are, primarily, due to modulation of gene expression. Therefore, the identification and study of IFNγ stimulated genes, signaling mediators and their cross talk with other cellular pathways is an active area of research.
The system of our study was a hepatoma cell line, H6, which is derived from a spontaneous tumor from B10.A mice and selected for in vitro cell culture. It is an IFNγ inducible system and has been used to study IFNγ-induced gene expression and functional responses. Treatment of H6 cells with IFNγ greatly enhanced MHC class I levels but also reduced cell growth. High amounts of reactive oxygen species (ROS) and reactive nitrogen intermediates (RNI) play crucial roles in the growth suppressive effect of IFNγ. To better understand the signaling pathways involved in the generation of ROS and RNI, the involvement of Ras was investigated. Ras-GTP levels were determined by pull down assays using GST-Raf1-Ras binding domain fusion protein bound to glutathione agarose. Ras activation (conversion of Ras-GDP to Ras-GTP) was observed in H6 cells upon IFNγ treatment by ~12 hr. To assess the functional role of Ras activation, studies with Manumycin A, a farnesyl transferase inhibitor (FTI), were performed. The formation of functional Ras requires farnesylation, a post-translational modification, which is inhibited by FTIs. Treatment with Manumycin A blocked Ras activation but did not significantly modulate the IFNγ-induced MHC class I. However, the inhibitor reduced ROS amounts leading to increased cell growth in the presence of IFNγ. Together, these results delineated the role of Ras and ROS in modulating some functions of IFNγ.
To further understand the mechanisms by which Ras mediates its functions during IFNγ mediated growth suppression, the activation and function of Ras effectors was evaluated. In particular, the role of Ras-like (Ral) guanyl nucleotide-binding proteins, RalA and RalB, was investigated. IFNγ induced transcripts of RalA but not RalB. Also, the induction of RalA and IFNγ induced growth suppression were Stat1-dependent. Studies involving chemical inhibitors and genetic studies revealed that Ras played a role in the induction of RalA during IFNγ treatment. The role of c-Jun N-terminal kinase (JNK), a stress induced kinase, was also elucidated in this system. Together, IFNγ induced activation of Ras and its effectors RalA and JNK, leading to high amounts of ROS that suppressed cell growth.
To evaluate the physiological significance of Ras activation during inflammatory responses, the mouse model of acetaminophen (APAP) induced liver injury was established. Hepatotoxicity due to overdose of the analgesic and antipyretic, APAP, is a major cause of liver failure in adults. APAP is metabolized into a reactive metabolite which binds to glutathione. Consequently, the depletion of intracellular glutathione stores leads to oxidative stress and liver injury. Notably, Ifnγ-/- mice are resistant to APAP-induced liver damage demonstrating a crucial role for this cytokine. The role of Ras activation was evaluated after oral dosing of BALB/c mice with APAP. Ras-GTP was induced early and decreased amounts were observed upon treatment with L-methionine, which replenished glutathione amounts. Injection with L-methionine or Manumycin A rescued liver injury as assessed by lowered serum alanine aminotransferase amounts and histological analysis. Kinetic studies were also performed, under different treatment conditions, to estimate different biochemical parameters: glutathione amounts, JNK activation, protein carbonylation, ROS amounts, serum amounts of cytokines, TNFα and IFNγ etc. This study reveals a role of Ras activation in stimulating proinflammatory responses and demonstrates the therapeutic efficacy of FTIs during APAP-induced liver injury. In addition the role of RalA during APAP-induced liver injury was also studied.
In summary, this study, involving in vitro cell culture and in vivo liver injury model systems, sheds light on the significant contributions of Ras and its effector, RalA, during IFNγ mediated growth suppression and APAP-induced liver injury.
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O2 Carrier Facilitated O2 Transport in a Hepatic Hollow Fiber BioreactorChen, Guo 01 November 2010 (has links)
No description available.
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Funktionelle Analyse von komplexen Hepatitis-B-Virus-Varianten, assoziiert mit Leberzirrhose bei ImmunsupprimiertenMärschenz, Stefanie 06 October 2006 (has links)
Obwohl der Wildtyp des Hepatitis-B-Virus (HBV) nicht zytopathogen und die Pathogenese der Hepatitis B generell immunvermittelt ist, können in immunsupprimierten Nierentransplantatempfängern mit chronischer Hepatitis B schwere Leberschäden bis hin zu Leberzirrhose und Leberversagen entstehen. Die Entwicklung von Leberzirrhose in den Nierentransplantierten ist assoziiert mit der Akkumulation und Persistenz von komplexen HBV-Varianten mit Mutationen im Core-Promotor / X-Gen, Deletionen im Core (C)-Gen und teilweise zusätzlichen Deletionen im präS-Bereich. Dies lässt eine Rolle der Varianten in der speziellen Pathogenese bei Immunsupprimierten vermuten. In der vorliegenden Arbeit wurden funktionelle Analysen der komplexen Varianten im Vergleich zu Referenz-Wildtypgenomen und Wildtyp-ähnlichen Genomen der Patienten aus der frühen Infektionsphase durchgeführt, um Hinweise auf den potentiellen Beitrag der Varianten zur Pathogenese zu erlangen. Die Analysen erfolgten durch transiente Transfektion der humanen Hepatomazelllinie HuH7 mit repräsentativen HBV-Gesamtgenomen, die aus 2 Patienten während des Krankheitsverlaufs von einer asymptomatischen Infektion hin zur Leberzirrhose isoliert und kloniert worden waren. Trotz einiger Unterschiede im Detail wiesen die komplexen Varianten einen gemeinsamen, drastisch vom Wildtyp abweichenden Phänotyp auf. Dieser war gekennzeichnet durch eine veränderte Transkription mit reduzierten präC- und Oberflächen-mRNAs und verstärkter Expression der prägenomischen RNA, eine starke Reduktion des häufigsten Spleißprodukts der prägenomischen RNA, SP1, eine extrem reduzierte oder fehlende Expression und/oder Sekretion aller Oberflächenproteine und des HBeAg, ein verändertes intrazelluläres Verteilungsmuster des schwach exprimierten Core-Proteins und teilweise der Oberflächenproteine sowie eine erhöhte Replikation und Anreicherung gegenüber Wildtyp-HBV aufgrund einer verstärkten reversen Transkription der prägenomischen RNA. Dieser Phänotyp basierte zum Teil auf den Mutationen in Core-Promotor und C-Gen, wurde jedoch deutlich durch zusätzliche Mutationen in den übrigen Genomabschnitten beeinflusst. Die vielfältigen Veränderungen der Varianten unterstützen ihren vermuteten Beitrag zur Pathogenese. / Although wild-type hepatitis B virus is not cytopathogenic and the pathogenesis of hepatitis B is generally immune mediated, also immuno-suppressed patients, such as renal transplant recipients, with chronic hepatitis B may develop liver cirrhosis and end-stage liver disease. In renal transplant recipients, the development of liver cirrhosis is associated with the accumulation and persistence of complex HBV variants with mutations in core promoter / X gene, deletions in core (C) gene and sometimes additional deletions in the preS region. This suggests a role of these variants in the special pathogenesis in immuno-suppressed patients. In the present work, the complex variants were functionally analyzed in comparison to reference wild-type genomes and wild-type-like HBV genomes from the early asymptomatic phase of infection. For the analyses, representative cloned full-length HBV genomes isolated from 2 patients before and during liver cirrhosis were transiently transfected into the human hepatoma cell line HuH7. In spite of some variations, the complex variants showed a common phenotype, which was drastically altered compared to wild-type. It was characterized by reduced preC and surface mRNAs and increased expression of pregenomic RNA, by a strong reduction of the major spliced pregenomic RNA, SP1, by a partial or complete defect in expression and/or secretion of surface proteins and HBeAg, by an aberrant intracellular localization of the weakly expressed core protein and in some cases of the surface proteins, and by an enhanced replication and enrichment over wild-type HBV due to an enhanced reverse transcription of variant pregenomic RNA. The phenotypic alterations were often based on the mutations in core promoter and C gene but were considerably influenced by the additional mutations in other genomic regions. The multiple functional changes of the variants support their assumed contribution to pathogenesis.
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Receptor mediated catabolism of plasminogen activatorsGrimsley, Philip George, Medical Sciences, Faculty of Medicine, UNSW January 2009 (has links)
Humans have two plasminogen activators (PAs), tissue-type plasminogen activator (tPA) and urokinase-type plasminogen activator (uPA), which generate plasmin to breakdown fibrin and other barriers to cell migration. Both PAs are used as pharmaceuticals but their efficacies are limited by their rapid clearance from the circulation, predominantly by parenchymal cells of the liver. At the commencement of the work presented here, the hepatic receptors responsible for mediating the catabolism of the PAs were little understood. tPA degradation by hepatic cell lines was known to depend on the formation of binary complexes with the major PA inhibitor, plasminogen activator inhibitor type-1 (PAI-1). Initial studies presented here established that uPA was catabolised in a fashion similar to tPA by the hepatoma cell line, HepG2. Other laboratories around this time found that the major receptor mediating the binding and endocytosis of the PAs is Low Density Lipoprotein Receptor-related Protein (LRP1). LRP1 is a giant 600 kDa protein that binds a range of structurally and functionally diverse ligands including, activated α2 macroglobulin, apolipoproteins, β amyloid precursor protein, and a number of serpin-enzymes complexes, including PA??PAI-1 complexes. Further studies for the work presented here centred on this receptor. By using radiolabelled binding assays, ligand blots, and Western blots on cultured cells, the major findings are that: (1) basal LRP1 expression on HepG2 is low compared to a clone termed, HepG2a16, but appears to increase in long term culture; (2) a soluble form of LRP1, which retains ligand-binding capacity, is present in human circulation; (3) soluble LRP1 is also present in cerebral spinal fluid where its role in neurological disorders such as Alzheimer??s disease is a developing area of interest; and (4) the release of LRP1 is a mechanism conserved in evolution, possibly as distantly as molluscs. The discovery, identification, and characterisation of soluble LRP1 introduces this protein in the human circulation, and presents a possible further level of regulation for its associated receptor system.
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