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Establishing Methods For Protein Purification And Activity Analysis For Pkn1 And Pkn5 From Chlamydia TrachomatisHatfield, Spencer 01 May 2016 (has links)
Chlamydia are Gram negative, obligate intracellular bacterial pathogens responsible for diseases that affect both animals and humans. Only two vaccines have been developed for Chlamydia, targeting C. felis and C. abortus, and development of antibiotic resistance and/or persistent infection forms has been documented for multiple species. Consequently, identification of new therapeutic targets is critical for prevention and treatment of chlamydial infections. These bacterial pathogens have a unique biphasic developmental cycle beginning with the infectious and environmentally stable elementary body, which enters a host cell and envelopes itself in the host membrane forming an inclusion. While residing in the inclusion, the EB transitions into the metabolically active and replicative reticulate body. The RB divides by binary fission before converting back into the EB and exiting the host cell by inclusion extrusion or cell lysis. The signals that initiate morphogenesis and the mechanism(s) mediating the transition between EB and RB forms are poorly understood. Eukaryote-like serine/threonine kinases (Hank’s type kinases) have recently been described to play major roles in cellular development and pathogenicity in prokaryotes. Chlamydia encode three Hank’s type kinase; Pkn1, PknD, and Pkn5. We hypothesize that these kinases control bacterial differentiation and metabolism by regulating protein activity via phosphorylation, making them potential targets for anti-chlamydial therapeutics. To aid in future efforts to elucidate the roles of these Hank’s type kinases in the physiology of C. trachomatis, my thesis developed protocols for the affinity purification of recombinant Pkn1 and Pkn5 and assessed the efficacy of a high-throughput kinase assay for Pkn1.
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Untersuchungen zum Einfluss von RhoA und der RhoA Effektorkinase PKN auf die TNF-induzierte Barrieredysfunktion in humanen intestinalen EpithelzellenGluth, Markus 18 June 2012 (has links)
Chronisch entzündliche Darmerkrankungen stellen eine Gruppe von chronischen, häufig in Schüben verlaufenden Erkrankungen mit rezidivierenden Entzündungen des Gastrointestinaltraktes dar. Es konnte gezeigt werden, dass eine gestörte Barrierefunktion einen wichtigen Schritt für die Pathogenese darstellt und dass das Zytokin Tumornekrosefaktor alpha (TNF) eine entscheidende Rolle dabei spielt. Die Rolle der kleinen GTPase RhoA bei der TNF-induzierten Barrieredysfunktion ist aufgrund der Komplexität der Signalwege nicht vollständig verstanden. Daher sollte der Einfluss von RhoA und der RhoA Effektorkinase PKN auf diese Prozesse in vitro mit Hilfe eines induzierbaren Expressionssystems untersucht werden, welches die kontrollierte Expression einer konstitutiv aktiven (KA) RhoA- und PKN-Mutante sowie einer dominant negativen (DN) PKN-Mutante ermöglichte. Die Induktion der KA RhoA Expression führte zu einer Störung der epithelialen Barriere. Eine simultane Interferon-gamma und TNF-Behandlung resultierte ebenfalls in einer gestörten Barrierefunktion, welche in KA RhoA Zellen weniger stark ausgeprägt war. Die TNF-Behandlung führte zu einer Aktivierung von PKN, weshalb dieses Protein ein Kandidat für die Vermittlung dieser Effekte darstellte. Inhibition von PKN mit Inhibitoren oder der Expression der DN Mutante führten zu einer Aggravierung der TNF-induzierten Barrieredysfunktion, welche durch eine Verringerung des transepithelialen elektrischen Widerstandes und eine erhöhte Ionenpermeabilität charakterisiert war. Diese Veränderungen wurden von einer Erhöhung des Myosin Leichtketten und NF-kappaB p65-Phosphorylierungsniveaus sowie von morphologischen Veränderungen begleitet. Im Gegensatz dazu konnten diese Veränderungen durch die Expression der KA PKN Variante abgeschwächt bzw. verhindert werden. Diese Ergebnisse liefern Hinweise auf eine potenzielle Rolle der RhoA Effektorkinase PKN bei der Modulation der TNF-induzierten Barrieredysfunktion in intestinalen Epithelzellen. / Inflammatory bowel diseases are relapsing systemic inflammatory diseases of the gastrointestinal tract associated with high morbidity and costs. A plethora of studies demonstrated that impaired intestinal barrier function is a key step in the pathogenesis of inflammatory bowel diseases and that the cytokine tumor necrosis factor alphpa (TNF) is of pivotal importance for this effect. Although the small GTPase RhoA has been implicated in the control of tight junction function, its role in TNF induced barrier dysfunction is not entirely understood due to the complexity of its downstream signaling pathways. Therefore, the contribution of RhoA and its effector kinase PKN on TNF induced barrier dysfunction was investigated in vitro. An inducible expression system that allowed the doxycyline controlled expression of a constitutively active (CA) RhoA and PKN mutant as well as a dominant negative (DN) PKN mutant was generated. Induction of CA RhoA expression led to an impaired epithelial barrier. Simultaneous Interferon-gamma and TNF treatment also resulted in barrier perturbation, but this defect was attenuated when CA RhoA was expressed. As treatment with TNF resulted in activation of the RhoA effector kinase PKN, this protein constitutes a candidate molecule for the mediation of these effects. Inhibition of PKN by inhibitory compounds as well as expression of a dominant negative PKN mutant aggravated TNF-induced barrier dysfunction, characterized by a decline in transepithelial electrical resistance and increased ion permeability. These alterations were accompanied by an increase in myosin light-chain and NF-kappaB p65 subunit phosphorylation level as well as morphological changes of the tight junctions. Conversely, expression of a CA PKN mutant attenuated or prevented these changes. These results provide support for a potential role of the RhoA effector kinase PKN in modulating the barrier disrupting effects of TNF in the intestinal epithelium.
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PKN1 is a novel therapeutic target to block serum response factor-dependent androgen receptor action in advanced prostate cancer.Venkadakrishnan, Varadha Balaji 30 September 2020 (has links)
No description available.
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