@phdthesis{Engelmann2023, author = {Engelmann, Daria Marie}, title = {Regulation of Mammalian Phosphoglycolate Phosphatase}, doi = {10.25972/OPUS-19957}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-199577}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2023}, abstract = {Mammalian phoshoglycolate phosphatase (PGP, also known as AUM) belongs to the ubiquitous HAD superfamily of phosphatases. As several other members of HAD phosphatases, the Mg2+-dependent dephosphorylation is conducted via a nucleophilic attack from a conserved aspartate residue in the catalytic cleft. The protein structure of PGP could not yet be solved entirely. Only a hybrid consisting of the PGP cap and the PDXP core (pyridoxal phosphatase, closest enzyme paralog) was crystallizable so far. PGP is able to efficiently dephosphorylate 2-phosphoglycolate, 2-phospho-L-lactate, 4-phospho-D-erythronate, and glycerol-3-phosphate in vitro which makes them likely physiological substrates. The first three substrates can be derived from metabolic side reactions (during glycolysis) and inhibit key enzymes in glycolysis and pentose phosphate pathway, the latter is situated at the intersection between glycolysis and lipogenesis. 2-phosphoglycolate can also be released in the context of repair of oxidative DNA damage. The activity of purified PGP can be reversibly inhibited by oxidation - physiologically likely in association with epidermal growth factor (EGF) signal transduction. In fact, an association between persistently lacking PGP activity (via downregulation) and the presence of hyperphosphorylated proteins after EGF stimulation has been identified. Reversible oxidation and transient inactivation of PGP may be particularly important for short-term and feedback regulatory mechanisms (as part of the EGF signaling). Furthermore, cellular proliferation in PGP downregulated cells is constantly reduced. Whole-body PGP inactivation in mice is embryonically lethal. Despite the many well-known features and functions, the knowledge about PGP is still incomplete. In the present work the influence of reactive oxygen species (ROS) on PGP activity in cells und a possible connection between oxidative stress and the proliferation deficit of PGP downregulated cells was investigated. For the experiments, a spermatogonial cell line was used (due to the high PGP expression in testis). PGP activity can be reversibly inhibited in cellular lysates by H2O2 (as a ROS representative). Reversible oxidation could thus indeed be physiologically important. More oxidative DNA damage (by bleomycin) showed no PGP-dependent effects here. EGF stimulation (as an inducer of transient and well-controlled ROS production), low concentrations of menadione (as an oxidant) and N-acetylcysteine (as an antioxidant) were able to approximate the proliferation rate in PGP downregulated cells to that of control cells. The redox regulation of PGP could thus have an influence on cellular proliferation as a feedback mechanism - a mechanism that could not take place in PGP downregulated cells. However, the connections are probably even more complex and cannot be elucidated by a sole examination of the proliferation rate. The present results can thus only be regarded as preliminary experiments. For a better understanding of the features and functions of PGP, this work then focused on specific regulation of enzyme activity by pharmacologically applicable small molecules. Four potent inhibitors had previously been identified in a screening campaign. In this work, three of these four inhibiting compounds could be further characterized in experiments with highly purified, recombinant murine and human PGP. Compounds \#2 and \#9 showed competitive inhibition properties with a markedly rising KM value with little or no change in vmax. The results were consistent for all tested protein variants: the murine and the human PGP as well as a PGP/PDXP hybrid protein. Compound \#1 was the most potent and interesting PGP-inhibitory molecule: less change in KM and a constant decrease in vmax as well as a lower impact on the PGP/PDXP hybrid hint at a mixed mode of inhibition as a combination of competitive and non-competitive inhibition. The characterization of the potential inhibitors can serve as a basis for further structural analysis and studies on the complex physiological role of PGP.}, subject = {Phosphoglykolatphosphatase}, language = {en} } @phdthesis{Moench2017, author = {M{\"o}nch, Romana}, title = {The Growth Factor PDGF and its Signaling Pathways in Colorectal Cancer}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-139100}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2017}, abstract = {A successful therapy for colorectal cancer (CRC), one of the most common malignancies worldwide, requires the greatest possible research effort. Of critical importance is an understanding of the relevant intracellular networks of signaling cascades, their activation, and the resulting cellular changes that are a prerequisite for a more successful CRC therapy. Vascular endothelial growth factor (VEGF) and the appropriate VEGF receptors represent molecular targets that have already been successfully implemented in the clinic (i.e. using monoclonal antibodies, tyrosine kinase inhibitors). However, for platelet derived growth factor (PDGF) and the relevant PDGF receptors, there are currently no clinically approved molecular therapeutics available. However, there are preliminary data to show that PDGF and its associated signaling pathways play an important role in CRC progression. In particular, the PI3K/Akt/mTOR pathway is emerging as an important intracellular partner of PDGF with which to control proliferation, migration, and angiogenesis in tumor cells. Therefore it was the objective of this work to investigate the multifactorial influence of PDGF on proliferation and metabolism, depending on CRC mutation status. The intention was to identify new therapeutic targets for future cancer therapy through analyses of PDGF-induced intracellular changes. For this purpose two human colorectal cancer cell lines were analyzed at gene and/or protein level for components of the PI3K/Akt/mTOR and MAPK signaling pathway, c-Myc, p53, and HIF1α (hypoxia-inducible-factor 1α). Changes in proliferation and metabolism, either during stimulation with PDGF and/or PI3K/Akt/mTOR inhibition, were also investigated. Experiments conducted at protein level during PDGF stimulation and/or PI3K/Akt/mTOR inhibition revealed changes in signaling pathways and crosstalk. The influence of the tumor suppressors (retinoblastoma, Rb), oncogenes (c-Myc, p53mut), and HIF1α during stimulation with PDGF, and their interactions in the tumor cell with respect to proliferation and glycolysis warrant further examination in terms of clinical treatment options. Investigations at the gene level of ex vivo samples (UICC I-IV) complete the study with regards to the clinical relevance of PDGF. PDGF stimulation increases tumor cell proliferation in HT29 cells via the PI3K/Akt/mTOR pathway rather than the MAPK pathway. However, if the PI3K/Akt/mTOR pathway is pharmacologically blocked, PDGF stimulation is mediated by inhibitory crosstalk through the MAPK pathway. Further analyses revealed that specific Akt inhibition impedes tumor cell growth, while PI3K inhibition had little effect on proliferation. Inhibitory crosstalk was found to be responsible for these different effects. Careful intervention strategies are therefore required if future therapies intend to make use of these specific signaling pathways. One aim of future research should be to gain a better understanding of the crosstalk between these signaling pathways. In this fashion, "over-inhibition" of the signal pathways, which would result in additional clinical side effects for patients, could be prevented. In late stage UICC, more mutation events occur, with tumorigenicity promoted by an increased mutation rate. Given that PDGF is increasingly expressed in the late UICC stages, our data would indicate that PDGF's effects are amplified with increasing malignancy. The activating effect of PDGF on the PI3K/Akt/mTOR pathway and subsequent changes in the activity of p53mut, Rb, c-Myc, and HIF1α, lead to an unfavorable prognosis for colon cancer patients. PDGF acts on colon cancer cells in an Akt-activating, glycolysis-dependent manner. PDGF increases glycolysis and the ability of CRC cells to adjust their energy metabolism. These activities should be taken as possible starting points with which to design therapeutic interventions for CRC therapy. PDGF, as another representative of the growth factor family, seems to play a similar role to VEGF in CRC. The data from this study underline the importance of the PDGF - PI3K/Akt/mTOR pathway-axis and its potential as a possible target in colorectal cancer. Thus PDGF represents an attractive therapeutic target, besides the VEGF/EGFR-based therapies already used in CRC.}, subject = {Dickdarmkrebs}, language = {en} } @phdthesis{Staykov2012, author = {Staykov, Nikola}, title = {The Role of the GABPα/β Transcription Factor In the Proliferation of NIH-3T3 Cells}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-67655}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2012}, abstract = {SUMMARY GABP is a heterodymeric member of Ets-family transcription factors. It consists of two subunits - GABPa which contains DNA binding domain and GABPb, which provides transcriptional activation domain and nuclear localization signal. GABPa/b complex is essential for transcriptional activation of multiple lineage-restricted and housekeeping genes, several viral genes, and in some cases might function as transcriptional repressor. Large variety of data indicates involvement of GABP in the complex regulation of cell growth, specified by quiescence, stimulation/proliferation, apoptosis and senescence. Expression level of GABPa subunit is rapidly increased when resting cells enter S-phase, and GABPa/b complex is critical to promote the continuity of the cell cycle. Conditional inactivation of GABPa expression in mouse embryonic fibroblasts results in a complete block of proliferation and acquisition of senescence-like phenotype. However, the influence of GABP on the other cell growth determinant - the apoptosis - remains largely obscure. Therefore we aimed to investigate the influence of GABPa/b expression level on the cell growth in vitro. Using siRNA approach we achieved efficient but only transient down-regulation of GABPa expression which precluded further cell growth studies. Persistent increase of the expression of GABPb subunit only resulted in a positive effect on the cell growth speed. Simultaneous conditional overexpression of both GABPa and GABPb subunits though, strongly reduced the growth of the affected cell cultures in reversible and in expression level dependent manner. Interestingly, GABPa/b overexpressing cells did show neither cell cycle arrest nor massive induction of apoptosis. However, more detailed analyses revealed that dampened apoptotic processes were taking place in GABPa/b-overexpressing cells, starting with a prominent activation of caspase-12. Interestingly, activation of downstream effector caspases was rather suppressed explaining a weak increase of apoptotic cells in GABPa/b overexpressing cultures. This effect suggests that the activation of caspase-12 by elevated amounts of exogenous GABPa/b reflects the normal physiological mechanism of caspase-12 regulation.}, subject = {Proliferation}, language = {en} } @phdthesis{Gelmedin2008, author = {Gelmedin, Verena Magdalena}, title = {Targeting flatworm signaling cascades for the development of novel anthelminthic drugs}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-33334}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2008}, abstract = {Echinococcus multilocularis verursacht die Alveol{\"a}re Echinokokkose (AE), eine lebendsbedrohliche Krankheit mit limitierten chemotherapeutischen M{\"o}glichkeiten. Die jetzige Anti-AE Chemotherapie basiert auf einer einzigen Wirkstoffklasse, den Benzimidazolen. Obwohl Benzimidazole in vitro parasitozid wirken, wirken sie in vivo bei AE-Behandlung lediglich parasitostatisch und rufen schwere Nebenwirkungen hervor. In F{\"a}llen operabler L{\"a}sionen erfordert die Resektion des Parasitengewebes {\"u}ber einen l{\"a}ngeren Zeitraum eine chemotherapeutische Unterst{\"u}tzung. Damit sind die jetzigen Behandlungsm{\"o}glichkeiten inad{\"a}quat und ben{\"o}tigen Alternativen. In der vorliegenden Arbeit wurden die Signalwege von Plattw{\"u}rmern analysiert, um potentielle Targets f{\"u}r neue therapeutische Ans{\"a}tze zu identifizieren. Dabei konzentrierte ich mich unter Anwendung von molekularbiologischer, biochemischer und zellbiologischer Methoden auf Faktoren, die an Entwicklung und Proliferation von E. multilocularis beteiligt sind. Darunter waren die drei MAP kinases des Parasiten EmMPK1, ein Erk1/2-Ortholog, EmMPK2, ein p38-Ortholog und EmMPK3, ein Erk7/8-Ortholog. Des Weiteren identifizierte und charakterisierte ich EmMKK2, ein MEK1/2-Ortholog des Parasiten, welches zusammen mit den bekannten Kinasen EmRaf und EmMPK1 ein Erk1/2-{\"a}hnliches MAPK Modul bildet. Ich konnte zudem verschiedene Einfl{\"u}sse von Wirtswachstumsfaktoren wie EGF (epidermal growth factor) und Insulin auf die Signalmechanismen des Parasiten und das Larvenwachstum zeigen, darunter die Phosphorylierung von Elp, ein Ezrin-Radixin-Moesin {\"a}hnliches Protein, die Aktivierung von EmMPK1 und EmMPK3 und eine gesteigerte mitotische Aktivit{\"a}t der Echinokokkenzellen. Zus{\"a}tzlich wurden verschiedene Substanzen auf ihre letale Wirkung auf den Parasiten untersucht, darunter befanden sich (1.) generelle Inhibitoren von Tyrosinkinasen (PP2, Leflunamid), (2.) gegen die Aktivit{\"a}t von Rezeptor-Tyrosin-Kinasen gerichtete Pr{\"a}parate, (3.) urspr{\"u}nglich anti-neoplastische Wirkstoffe wie Miltefosin und Perifosin, (4.) Inhibitoren von Serin/ Threonin-Kinasen, die die Erk1/2 MAPK Kaskade blockieren und (5.) Inhibitoren der p38 MAPK. In diesen Untersuchungen hat sich EmMPK2 aus den folgenden Gr{\"u}nden als vielversprechendes Target erwiesen. Aminos{\"a}uresequenz-Analysen offenbarten einige Unterschiede zu menschlichen p38 MAP Kinasen, welche sehr wahrscheinlich die beobachtete gesteigerte basale Aktivit{\"a}t des rekombinanten EmMPK2 verursachen, verglichen mit der Aktivit{\"a}t humaner p38 MAPK-\&\#945;. Zus{\"a}tzlich suggerieren die prominente Autophosphorylierungsaktivit{\"a}t von rekombinantem EmMPK2 und das Ausbleiben einer Interaktion mit den Echinococcus MKKs einen unterschiedlichen Regulierungsmechanismus im Vergleich zu den humanen Proteinen. Die Aktivit{\"a}t von EmMPK2 konnte sowohl in vitro als auch in kultivierten Metazestodenvesikeln durch die Behandlung mit SB202190 und ML3403, zwei ATP kompetitiven Pyridinylimidazolinhibitoren der p38 MAPK, in Konzentrations-abh{\"a}ngiger Weise inhibiert werden. Zudem verursachten beide Substanzen, insbesondere ML3403 die Inaktivierung von Parasitenvesikeln bei Konzentrationen, die kultivierte S{\"a}ugerzellen nicht beeintr{\"a}chtigten. Ebenso verhinderte die Anwesenheit von ML3403 die Generation von neuen Vesikeln w{\"a}hrend der Kultivierung von Echinococcus Prim{\"a}rzellen. Das Targeting von Mitgliedern des EGF-Signalwegs, insbesondere der Erk1/2-{\"a}hnlichen MAPK Kaskade mit Raf- und MEK- Inhibitoren verhinderte die Phosphorylierung von EmMPK1 in in vitro kultivierten Metazestoden. Obwohl das Parasitenwachstum unter diesen Konditionen verhindert wurde, blieb die strukturelle Integrit{\"a}t der Metazestodenvesikeln w{\"a}hrend der Langzeitkultivierung in Anwesenheit der MAPK Kaskade-Inhibitoren erhalten. {\"A}hnliche Effekte wurden beobachtet nach Behandlung mit den anderen zuvor aufgef{\"u}hrten Inhibitoren. Zusammenfassend l{\"a}sst sich festhalten, dass verschiedene Targets identifiziert werden konnten, die hoch sensibel auf die Anwesenheit der inhibitorischen Substanzen reagierten, aber nicht zum Absterben des Parasiten f{\"u}hrten, mit Ausnahme der Pyridinylimidazolen. Die vorliegenden Daten zeigen, dass EmMPK2 ein {\"U}berlebendsignal vermittelnden Faktor darstellt und dessen Inhibierung zur Behandlung der AE benutzt werden k{\"o}nnte. Dabei erwiesen sich p38 MAPK Inhibitoren der Pyridinylimidazolklasse als potentielle neue Substanzklasse gegen Echinokokken.}, subject = {Fuchsbandwurm}, language = {en} }