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The utilization of Ginkgo biloba in medicinal practice dates back to 1505 A.D. Ironically, the mechanisms of action of Ginkgo are not fully clarified till now. Nowadays, Ginkgo biloba leaf extracts are mainly indicated for mild to moderate cerebrovascular insufficiency and different forms of dementia. The fact that it is an herbal extract composed of several different components indeed adds to the intricacy of finding its mechanisms of actions. Indisputably, many scientists tried to elucidate the mechanisms of actions of Ginkgo. The first step to achieve this goal was to standardize the leaf extract. The standardized Ginkgo leaf extract contains 22-27 % flavonol glycosides, 2.8-3.4 % of ginkgolide A, B and C, as well as approximately 2.6-3.2 % bilobalide and below 5 ppm ginkgolic acids. A widespread standardized Ginkgo extract is the EGb 761, which was utilized in the current work. One of the earliest proposed mechanisms is the ability of the Ginkgo extract to act as an anti-oxidant, which could be explained by its high flavonoid contents. However, without doubt EGb 761 encompasses other characteristics which distinguish it from other herbal extracts that are also rich in flavonoids. Since free radicals and reactive oxygen species are highly associated with the mitochondrial functions, examination of the effect of EGb 761 on mitochondrial functions was lately addressed. Moreover, this was encouraged as the link between Alzheimer’s disease [AD] and the mitochondria started to emerge. Previously, our group observed mitochondrial protective actions of EGb 761 on cell culture in vitro. Furthermore, anti-apoptotic effects were previously described for EGb 761. However, only very few studies addressed the single constituents and their effect on mitochondrial functions. Flavonoids were studied in several other plant extracts and their radical scavenging activity is unquestionable, but EGb 761 has anti-apoptotic actions which may be attributed to its terpenoid fraction. Exclusively found in the Ginkgo plant, are the ginkgolides and therefore their actions are not yet fully elucidated. Moreover, those who attempted to address these constituents concentrated on one or two candidates, for example bilobalide or ginkgolide B and ignored the rest. Unfortunately, this led to incomplete results, and one couldn’t compare the relative activities of all EGb 761 components in order to state whether all the components are effective or not. ...
Inhibitor of Apoptosis (IAP) proteins are expressed at high levels in many cancers and contribute to apoptosis resistance. Therefore, they represent promising anticancer drug targets. Here, we report that small molecule IAP inhibitors at subtoxic concentrations cooperate with monoclonal antibodies against TRAIL receptor 1 (Mapatumumab) or TRAIL receptor 2 (Lexatumumab) to induce apoptosis in neuroblastoma cells in a highly synergistic manner (combination index <0.1). Importantly, we identify RIP1 as a critical regulator of this synergism. RIP1 is required for the formation of a RIP1/FADD/caspase-8 complex that drives caspase-8 activation, cleavage of Bid into tBid, mitochondrial outer membrane permeabilization, full activation of caspase-3 and caspase-dependent apoptosis. Indeed, knockdown of RIP1 abolishes formation of the RIP1/FADD/caspase-8 complex, subsequent caspase activation and apoptosis upon treatment with IAP inhibitor and TRAIL receptor antibodies. Similarly, inhibition of RIP1 kinase activity by Necrostatin-1 inhibits IAP inhibitor- and TRAIL receptor-triggered apoptosis. By comparison, over-expression of the dominant-negative superrepressor IκBα-SR or addition of the TNFα-blocking antibody Enbrel does not inhibit IAP inhibitor- and Lexatumumab-induced apoptosis, pointing to a NF-κB- and TNFα-independent mechanism. Of note, IAP inhibitor also significantly reduces TRAIL receptor-mediated loss of cell viability of primary cultured neuroblastoma cells, underscoring the clinical relevance. By demonstrating that RIP1 plays a key role in the IAP inhibitor-mediated sensitization for Mapatumumab- or Lexatumumab-induced apoptosis, our findings provide strong rationale to develop the combination of IAP inhibitors and TRAIL receptor agonists as a new therapeutic strategy for the treatment of human cancer.
Remodeling of extracellular matrix (ECM) is an important physiologic feature of normal growth and development. In addition to this critical function in physiology many diseases have been associated with an imbalance of ECM synthesis and degradation. In the kidney, dysregulation of ECM turnover can lead to interstitial fibrosis, and glomerulosclerosis. The major physiologic regulators of ECM degradation in the glomerulus are the large family of zinc-dependent proteases, collectively refered to matrix metalloproteinases (MMPs). The tight regulation of most of these proteases is accomplished by different mechanisms, including the regulation of MMP gene expression, the processing and conversion of the inactive zymogen by other proteases such as serine proteases and finally the inhibition of active MMPs by endogenous inhibitors of MMPs, denoted as tissue inhibitors of metalloproteinases (TIMPs). Namely, the MMP-9 has been shown to be critically involved in the dysregulation of ECM turnover associated with severe pathologic conditions such as rheumatoid arthritis or fibrosis of lung, skin and kidney. In the present work I searched for a possible modulation of MMP-9 expression and/or activity in glomerular mesangial cells which are thought as key players of many inflammatory and non-inflammatory glomerular diseases. I found that various structurally different PPARalpha agonists such as WY-14,643, LY-171883 and fibrates potently suppress the cytokine-induced MMP-9 expression in renal MC. Furthermore, I demonstrate that the inhibition of MMP-9 expression by PPARalpha agonists was paralleled by a strong increase of cytokine-induced iNOS expression and subsequent NO formation, suggesting that PPARalpha-dependent effects on MMP-9 expression level primarily result from alterations in NO production which in turn reduces the MMP-9 mRNA half-life. Searching for the detailed mechanism of NO-dependent effects on MMP-9 mRNA stability, I found that NO either given from exogenous sources or endogenously produced increases the MMP-9 mRNA degradation by decreasing the expression of the mRNA stabilizing factor HuR. Furthermore, I demonstrate a reduction in the RNA-binding capacity of HuR containing complexes to MMP-9 ARE motifs in cells treated with NO. Since the reduction of HuR expression can be mimicked by the cGMP analog 8-Bromo-cGMP, I suggest that NO reduces in a cGMP-dependent manner the expression of HuR. Finally, I elucidated the modulatory effect of extracellular nucleotides, mainly ATP, on cytokine-triggered MMP-9 expression. Interestingly, I found that in contrast to NO, gamma-S-ATP the stable analog of ATP potently amplifies the IL-beta mediated MMP-9 expression. The increase in mRNA stability was paralleled by an increase in the nuclear-cytosolic shuttling of the mRNA stabilizing factor HuR. Furthermore, I demonstrate an increase in the RNA-binding capacity of HuR containing complexes to the 3'-UTR of MMP-9 by ATP. In summary, the data presented here may help to find new targets (posttranscriptional regulation) that could be used to manipulate or modulate the expression of not only MMP-9 but also other genes regulated on the level of mRNA stability.
Systematisch verabreichte Chemotherapeutika sind oft uneffektiv bei der Behandlung von Krankheiten des zentralen Nervensystems (ZNS). Eine der Ursachen hierfür ist der unzureichende Arzneistoff-Transport ins Gehirn aufgrund der Blut-Hirn-Schranke. Eine der Strategien für den nicht-invasiven Wirkstoff-Transport ins Gehirn ist die Verwendung von Nanopartikeln. Polybutylcyanoacrylat-Nanopartikel, die mit Polysorbat 80 (Tween® 80) überzogen wurden, können die Blut-Hirn-Schranke passieren und somit Wirkstoffe ins Gehirn transportieren. Wird die Blut-Hirn-Schranke durch einen Hirntumor partiell beschädigt und hierdurch ihre Permeabilität am Ort des Tumors erhöht, können Nanopartikel den Tumor zusätzlich durch den sogenannten EPR-Effekt erreichen. Im ersten Teil der vorliegenden Arbeit wurde die Beladung der Nanopartikel durch Variation der Formulierungparameter mit dem Ziel optimiert, eine Formulierung mit höherer Wirksamkeit für die Therapie von Glioblastom-tragenden Ratten zu entwickeln. Außerdem wurde das Potential von Doxorubicin, das an mit „Stealth Agents“ überzogenen Polybutylcyanoacrylat-Nanopartikel gebunden war, für die Chemotherapie von Hirntumoren untersucht. Im zweiten Teil dieser Studie wurden die Gehirn- und Körperverteilung in gesunden und in Glioblastom-101/8-tragenden Ratten nach i.v.-Gabe von Poly(butyl-2-cyano[3- 14C]acrylat)-Nanopartikeln, die mit Polysorbat 80 beschichtet wurden, und solchen, die noch zusätzlich mit Doxorubicin geladen waren (DOX-14C-PBCA + PS), untersucht. Die Standardformulierung von Doxubicin-Polybutylcyanoacrylat-Nanopartikeln (DOX-NP) wurde durch anionische Polymerisierung von Butylcyanoacrylat in Anwesenheit von DOX hergestellt. Zusätzlich wurden unterschiedliche DOX-NP Formulierungen durch Veränderung der Herstellung produziert. Das therapeutische Potential der Formulierungen wurde in Ratten mit ins Gehirn transplantieren Glioblastom 101/8 untersucht. Neben Polysorbat 80 wurden Poloxamer 188 und Poloxamin 908 als Überzugsmaterial verwendet. Die Resultate ergaben, dass die mit Polysorbat 80 überzogene Standardformulierung am effektivsten war. Die höhere Wirksamkeit von DOX-NP+PS 80 könnte durch die Fähigkeit dieser Träger erklärt werden, den Wirkstoff während eines frühen Stadiums der Tumorentwicklung durch einen Rezeptor-vermittelten Mechanismus, der durch den PS 80-Überzug aktiviert wurde über die intakte Blut-Hirn-Schranke, zu transportieren. Unsere Ergebnisse zeigen auch, dass Poloxamer 188 und Poloxamin 908 den antitumoralen Effekt von DOX-PBCA beträchtlich verbessern. Der anti-tumorale Effekt dieser Formulierungen könnte möglicherweise dem EPR-Effekt zugeschrieben werden. Es ist bekannt, dass die tumorale Arzneistoff-Aufnahme durch den EPR-Effektes für lang-zirkulierende Wirkstoffträger ausgeprägter ist und so mehr Wirkstoff durch die Tumor-geschädigte Blut-Hirn-Schranke gelangt. Unbeschichtete Nanopartikel, Polysorbat 80-beschichtete Nanopartikel oder mit Doxorubicin beladene und mit Polysorbat 80 beschichtete Nanopartikel wurden in gesunden und Tumor-tragenden Ratten injiziert. Diese Nanopartikel-Präparationen zeigten einer unterschiedliche Korpenverteilung in den Ratten. Unbeschichtete Nanopartikel sammelten sich in den RES-Organen an. Mit PS 80 beschichtete NP reduzierten die Aufnahme der NP in Leber und Milz, während sich die Konzentration der NP in der Lunge erhöhte. Diese Beobachtungen deuten darauf hin, dass die Änderung der Oberflächeneigenschaften der NP durch das Tensid, zu einer Interaktion mit unterschiedlichen Opsoninen führt, welches die Aufnahme der NP von verschiedenen phagozitierenden Zellen erleichtert. Hingegen war die Aufnahme der mit DOX beladenen, PS 80-beschichteten Nanopartikel den unbeschichteten Partikel ähnlich. Im Vergleich mit gesunden Ratten und mit Tumor-tragenden Ratten hingegen war die Konzentration der NP im Gehirn von Tumor tragenden Ratten 10 Tage nach der Tumor-implantation signifikant höher. In Anwesenheit des Glioblastoms ist der Transport von NP in das Gehirn das Resultat verschiedener Faktoren: zusätzlich zur Fähigkeit von PS 80-Nanopartikeln, die Blut-Hirn-Schranke zu passieren, extravasieren diese Träger wegen des EPR Effekts über das durch den Tumor undichte Endothelium. Die Konzentration von PS 80 [14C]-PBCA NP war im Glioblastom signifikant höher als mit DOX [14C]-PBCA NP. Dieses Phänomen kann durch die unterschiedliche Mikroumgebung von zerebralem intra-tumoralen und intaktem Gehirngewebe erklärt werde. Insbesondere können sich die positive Ladung der tumoralen Regionen und die positive Ladung der DOX [14C]-PBCA NP negativ beeinflussen. Dennoch waren die Doxorubicin-Konzentration in Glioblastom ausreichend, einen therapeutischen Effekt zu ermöglichen.
Top-down and bottom-up approaches are the general methods used to analyse proteomic samples today, however, the bottom-up approach has been dominant in the last decade. Establishing a bottom-up method involves not only the choice of adequate instruments and the optimisation of the experimental parameters, but also choosing the right experimental conditions and sample preparation steps. LC-ESI MS/MS has widely been used in this field due to its advanced automation. The primary objective of the present study was to establish a sensitive high-throughput nLC-MALDI MS/MS method for the identification and characterisation of proteins in biological samples. The method establishment included optimisation and validation of parameters such as the capillaries in the HPLC systems, gradient slopes, column temperature, spotting frequencies or the MS and MS/MS acquisition methods. The optimisation was performed using two HPLC-systems (Agilent 1100 series and Proxeon Easy nLC system), three spotters and the 4800 MALDI-TOF/TOF analyzer. Furthermore, samples preparation protocols were modified to fit to the established nLCMALDI- TOF/TOF-platform. The potentials of this method was demonstrated by the successful analysis of complex protein samples isolated from lipid particles, pre-adipocytes/adipocytes tissues, membrane proteins and proteins pulled-down from protein-proteins interaction studies. Despite the small amount of proteins in the lipid particles or oil bodies, and the challenges encountered in studying such proteins, 41(6 novel + 14 mammal specific + 21 visceral specific) proteins were added to the already existing proteins of the secretome of human subcutaneous (pre)adipocytes and 6 novel proteins localised in the yeast lipid particles. Protein-protein interaction studies present another area of application. Here the analytical challenges are mostly due to the loss of binding partner upon sample clean-up and to differentiate from non-specific background. Novel interaction partners for AF4•MLL and AF4 protein complex were identified. Furthermore, a novel sample protocol for the analysis of membrane proteins, based on the less specific protease, elastase, was established. Compared to trypsin, a higher sequence coverage and higher coverage of the transmembrane domains were achieved. The use of this enzyme in proteomics has been limited because of its non specific cleavage. However, from the results obtained in these studies, elastase was found to cleave preferentially at the C-terminal site of the amino acids AVLIST. The advantage of the established protocol over conventional protocols is that the same enzyme can be used for shaving of the soluble dormains of intact proteins in membranes and the digestion of the hydrophobic domain after solubilisation. Furthermore, the solvents used are compatible with the nLC-MALDI method setup. In addition, it was also shown that for less specific enzymes, a higher mass accuracy is required to reduce the rate of false positive identifications, since current search engines are not perfectly adapted for these types of enzymes. A brief statistical analysis of the MS/MS data obtained from the LC-MALDI TOF/TOF system showed that for less specific enzymes, under high-energy collision conditions, approximately 43 % of the fragment ions could not be matched to the known y- b type ions and their resultant internal fragments. This limitation greatly influenced the search results. However, this limitation can be overcome by modifying the N-terminal amino acids with basic moieties such as TMT. The use of elastase as a digestion enzyme in proteomic workflow further increased the complexity of the sample. Therefore, orthogonal multidimensional separation was necessary. Offgel-IEF was used as the separation technique for the first dimension. Here peptides are separated according to the pI. However, the acquired samples could not be loaded to the nLC due to the high viscosity of the concentrated samples when using the standard protocol. In order to achieve compatibility of the Offgel-IEF to the nLC-MALDI-TOF/TOF-platform, the separation protocol of the Offgel-IEF was modified by omitting the glycerol, which was the cause of the viscous solution. The novel glycerol free protocol is advantageous over the conventional method because the samples could directly be picked-up and loaded onto the pre-column without resulting in an increase in back pressure or a subsequent pre-column clogging. The glycerol free protocol was then assessed using purple membrane and membrane fraction of C. glutamicum. The results obtained were comparable to those applied in published reports. Therefore, the absence of glycerol did not affect the separation efficiency of the Offgel-IEF. In addition the applicability of elastase and the glycerol free Offgel-IEF for quantitation of membrane proteins was assessed. Most of the unique peptides identified were in the acidic region and 85 % were focused only into one fraction and approximately 95 % in only two fractions. These results are in accordance with previously published results (Lengqvist et al., 2007). When compared with theoretical digests of the proteins identified in this study, it can be concluded that basic moiety (TMT) on the peptide backbone, did not affect the separation efficiency of the Offgel-IEF. In an applied study, changes in the protein content of yeast strain grown in two different media were relatively quantified. For example, prominent proteins, such as the hexose tranporter proteins responsible for transporting glucose accross the membrane, were successfully quantified. Last but not least, the nLC-MALDI-TOF/TOF platform also served as a basis for the development of a high-throughput method for the identification of protein phosphorylation. The establishment of such a method using MALDI has been challenging due to the lack of sensitive matrices, such as CHCA for non-modified peptides, which exhibit a homogenous crystallisation and thus yield stable signal intensity over a long period of time in an automated setup. The first step of this method was the establishment of a matrix/matrix mixture with better crystal morphology and higher analyte signal intensity than the matrix of choice, i.e. DHB. From MS and MS/MS measurements of standard phosphopeptides, a combination of FCCA and CHAC in a 3:1 ratio and 3 mM NH4H2PO4 facilitated high analyte signal intensities and good fragmentation behaviour. Combining a custom-packed biphasic column for the enrichment of phosphopeptides, the applicability of the matrix mixture was assessed in anautomated phosphopeptide analysis using standard phosphopeptides spiked to a 20-fold excess BSA digest. These analyses showed that this method is reproducibile and both flow throughs can be analysed. Applying the method to the analysis of 2 standard phosphoproteins, alpha/beta-casein, and a leukemia related protein, ENL, 13 phosphopeptides from both alpha/beta-Casein and 13 phosphopeptides with 6 phosphorylation sites from the ENL were identified. As a general conclusion, it can be stated that the nLC-MALDI-TOF/TOF method established here in various modifications for different analytical purposes is a robust platform for proteomic analyses.
P2X receptor subunits assemble in the ER of Xenopus oocytes to homomultimeric or heteromultimeric complexes that appear as ATP-gated cation channels at the cell surface. In this work it was intended to investigate the posttranslational modifications such as N-linked glycosylation and disulfide bond formation that is undergone by P2X1 receptors. In addition, the aim of this study was to examine the expression and the quaternary structure of selected P2X receptor isoforms in Xenopus oocytes. The investigation of the quaternary structure of the metabolically or surface labeled His-P2X2 receptor by BN-PAGE revealed that, while the protein complex is only partially assembling in oocytes, the plasma membrane form of the His-P2X2 receptor assembled into trimeric and even hexameric complex as was shown by the BN-PAGE analysis. Besides this finding, it is shown that the His-P2X5 protein that was purified from metabolically or surface labeled oocytes appeared as one single band corresponding to a trimer when analyzed by BN-PAGE. The present study signified that His-P2X6 alone does not reach a defined assembly status and possibly needs the hetero-polymerisation with other P2X subunits to assemble properly for insertion into the plasma membrane. Another finding of this study is that the P2X1 and P2X2 subunits could exist as heteromultimeric protein complexes in the plasma membrane of cells. Purification of surface expressed His-P2X2 subunit allowed the detection of co-injected P2X1 subunit and vice versa in Xenopus oocytes. Incubation with glutardialdehyde led to the cross-linking of P2X2 and P2X1 subunits to dimers and trimers. BN-PAGE analysis of the P2X2/P2X1 complex isolated under nondenaturing conditions from surface-labeled oocytes yielded one distinct band corresponding to a trimeric complex. The analysis of a C-terminally GFP tagged His-P2X1 fusion protein by confocal fluorescence microscopy revealed small clusters of the protein complexes, approximately 4-6 µm in diameter from a diffuse distribution of the protein in the plasma membranes of Xenopus oocytes. The cross-linking or BN-PAGE analysis of the fusion protein resulted in proteins that migrated quantitatively as trimers when purified in digitonin. The analysis of some chimeric constructs confirmed the results of others, which showed that desensitization can be removed from the P2X1 or P2X3 receptor by providing the N-domain from the P2X2 receptor (Werner et al., 1996) The exchange of this domain did not alter the quaternary structure of the chimeras, which showed to be present as trimers when expressed in oocytes. In addition, glycan minus mutants of His-P2X1 receptor were analyzed to examine whether carbohydrate side chains are important for P2X1 subunit assembly, surface expression, or ligand recognition. SDS-PAGE analysis of glycan minus mutants carrying Q instead of N at five individual NXT/S sequons reveals that 284N remains unused because of a proline in the 4 position. The four other sites (153Asn, 184N, 210N, and 300N) carry N-glycans, but solely 300N acquires complex-type carbohydrates. Like parent P2X1 receptor, glycan minus mutants migrate as homotrimers when resolved by blue native PAGE. Recording of ATP-gated currents revealed that elimination of 153N or 210N diminishes or increases functional expression levels, respectively. In addition, elimination of 210N causes a 3-fold reduction of the potency for ATP. If three or all four N-glycosylation sites are simultaneously eliminated, formation of P2X1 receptors is severely impaired or abolished, respectively. It is concluded that at least one N-glycan per subunit of either position is absolutely required for the formation of P2X1 receptors. The SDS-PAGE analysis of surface-labeled His-P2X2 and His-P2X5 receptors revealed that, while the His-P2X2 subunit acquires three complex-type carbohydrates, in case of His-P2X5 polypeptide, only two of the three N-glycans could obtain complex-type carbohydrates during transit of the Golgi apparatus. Furthermore, it was shown that DTT treatment blocked the appearance of newly made His-P2X1 at the plasma membranes of Xenopus oocytes. Also, it was revealed that the effects of DTT on His-P2X1 biogenesis are fully reversible. Removal of the reducing agent leads to subsequent folding and assembly into His-P2X1 receptor complex, followed by transport to the cell surface. The characterization of cysteine minus mutants by SDS PAGE and BN-PAGE demonstrated that, the cysteine substitution in the first cysteine rich domain (C1 - C6) does not have a major effect on assembly for the mutant receptors. In contrast, the replacement of the four cysteine residues (C7 - C10) from the second cysteine rich domain demonstrate a critical importance of this domain for the functional surface expression of P2X1 receptor. The investigations of several double cysteine mutants revealed that according to a similarity in the sensitivity to ATP, the C1 and C6, as well as C2 and C4 and finally C3 and C5 are pairs forming two disulfide bonds in each P2X1 subunit.
Alzheimer’s disease (AD) is the most common neurodegenerative disorder world wide, causing presenile dementia and death of millions of people. During AD damage and massive loss of brain cells occur. Alzheimer’s disease is genetically heterogeneous and may therefore represent a common phenotype that results from various genetic and environmental influences and risk factors. In approximately 10% of patients, changes of the genetic information were detected (gene mutations). In these cases, Alzheimer’s disease is inherited as an autosomal dominant trait (familial Alzheimer’s disease, FAD). In rare cases of familial Alzheimer’s disease (about 1-3%), mutations have been detected in genes on chromosomes 14 and 1 (encoding for Presenilin 1 and 2, respectively), and on chromosome 21 encoding for the amyloid precursor protein (APP), which is responsible for the release of the cell-damaging protein amyloid-beta (ß-amyloid, Aß). Familial forms of early-onset Alzheimer’s disease are rare; however, their importance extends far beyond their frequency, because they allow to identify some of the critical pathogenetic pathways of the disease. All familial Alzheimer mutations share a common feature: they lead to an enhanced production of the Aß, which is the major constituent of senile plaques in brains of AD patients. New data indicates that Aß promotes neuronal degeneration. Therefore, one aim of these thesis was to elucidate the neurotoxic biochemical pathways induced by Aß, investigating the effect of the FAD Swedish APP double mutation (APPsw) on oxidative stress-induced cell death mechanisms. This mutation results in a three- to sixfold increased Aß production compared to wild-type APP (APPwt). As cell models, the neuronal PC12 (rat pheochromocytoma) and the HEK (human embryonic kidney 293) cell lines were used, which have been transfected with human wiltyp APP or human APP containing the Swedish double mutation. The used cell models offer two important advantages. First, compared to experiments using high concentrations of Aß at micromolar levels applied extracellularly to cells, PC12 APPsw cells secret low Aß levels similar to the situation in FAD brains. Thus, this cell model represents a very suitable approach to elucidate the AD-specific cell death pathways mimicking physiological conditions. Second, these two cell lines (PC12 and HEK APPwt and APPsw) with different production levels of Aß may additionally allow to study dose-dependent effects of Aß. The here obtained results provide evidence for the enhanced cell vulnerability caused by the Swedish APP mutation and elucidate the cell death mechanism probably initiated by intracellulary produced Aß. Here it seems likely that increased production of Aß at physiological levels primes APPsw PC12 cells to undergo cell death only after additional stress, while chronic high levels in HEK cells already lead to enhanced basal apoptotic levels. Crucial effects of the Swedish APP mutation include the impairments of cellular energy metabolism affecting mitochondrial membrane potential and ATP levels as well as the additional activation of caspase 2, caspase 8 and JNK in response to oxidative stress. Thereby ,the following model can be proposed: PC12 cells harboring the Swedish APP mutation have a reduced energy metabolism compared to APPwt or control cells. However, this effect does not leads to enhanced basal apoptotic levels of cultured cells. An exposure of PC12 cells to oxidative stress leads to mitochondrial dysfunction, e.g., decrease in mitochondrial membrane potential and depletion in ATP. The consequence is the activation of the intrinsic apoptotic pathway releasing cytochrome c and Smac resulting in the activation of caspase 9. This effect is amplified by the overexpression of APP, since both APPsw and APPwt PC12 cells show enhanced cytochrome c and Smac release as well as enhanced caspase 9 activity as vector transfected control. In APPsw PC12 cells a parallel pathway is additionally emphased. Due to reduced ATP levels or enhanced Aß production JNK is activated. Furthermore, the extrinsic apoptotic pathway is enhanced, since caspase 8 and caspase 2 activation was clearly enhanced by the Swedish APP mutation. Both pathways may then converge by activating the effector enzyme, caspase 3, and the execution of cell death. In addition, caspase independent effects also needs to be considered. One possibility could be the implication of AIF since AIF expression was found to be induced by the Swedish APP mutation. In APPsw HEK cells high chronic Aß levels leads to enhanced apoptotic levels, reduce mitochondrial membrane potential and ATP levels even under basal conditions. Summarizing, a hypothetical sequence of events is proposed linking FAD, Aß production, JNK-activation, mitochondrial dysfunction with caspase pathway and neuronal loss for our cell model. The brain has a high metabolic rate and is exposured to gradually rising levels of oxidative stress during life. In Swedish FAD patients the levels of oxidative stress are increased in the temporal inferior cortex. This study using a cell model mimicking the in vivo situation in AD brains indicates that probably both, increased Aß production and the gradual rise of oxidative stress throughout life converge at a final common pathway of an increased vulnerability of neurons to apoptotic cell death from FAD patients. Presenilin (PS) 1 is an aspartyl protease, involved in the gamma-secretase mediated proteolysis of Amyloid-ß-protein (Aß), the major constituent of senile plaques in brains of Alzheimer’s disease (AD) patients. Recent studies have suggested an additional role for presenilin proteins in apoptotic cell death observed in AD. Since PS 1 is proteolytic cleaved by caspase 3, it has been prosposed that the resulting C-terminal fragment of PS1 (PSCas) could play a role in signal transduction during apoptosis. Moreover, it was shown that mutant presenilins causing early-onset of familial Alzheimer's disease (FAD) may render cells vulnerable to apoptosis. The mechanism by which PS1 regulates apoptotic cell death is yet not understood. Therefore one aim of our present study was to clarify the involvement of PS1 in the proteolytic cascade of apoptosis and if the cleavage of PS1 by caspase 3 has an regulatory function. Here it is demonstrated that both, PS1 and PS1Cas lead to a reduced vulnerability of PC12 and Jurkat cells to different apoptotic stimuli. However a mutation at the caspase 3 recognition site (D345A/ PSmut), which inhibits cleavage of PS1 by caspase 3, show no differences in the effect of PS1 or PSCas towards apoptotic stimuli. This suggest that proteolysis of PS1 by caspase 3 is not a determinant, but only a secondary effect during apoptosis. Since several FAD mutation distributed through the whole PS1 gene lead to enhanced apoptosis, an abolishment of the antiapoptotic effect of PS1 might contribute to the massive neurodegeneration in early age of FAD patients. Here, the regulate properties of PS1 in apoptosis may not be through an caspase 3 dependent cleavage and generation of PSCas, but rather through interaction of PS1 with other proteins involved in apoptosis.
IL-18, a recently identified member of IL-1 family, is now recognized as an important regulator of innate and acquired immune responses. Therefore, the antitumor activities of IL-18 have been investigated. IL-18 has been shown to induce IFN-γ production by T, B, and NK cells, enhances NK cell activity, activates Fas ligandmediated apoptosis of the tumor cells, and improves the overall antitumor immunity. KG-1 cells were derived from a patient with acute myeloid leukemia (AML). IL-18 has been shown to induce IFN-γ production in those leukemic cells. TLR-3, in addition to its ability to recognize viral double stranded RNA, also can recognize the synthetic analogue poly(I:C) and induces type I IFN, inflammatory cytokine production, e.g TNF-α, and maturation of denderitic cells. In the present work the potential modulatory effect of PIC on IFN-γ and TNF-α production by KG-1 cells treated with IL-18 was investigated. Indeed, PIC strongly amplified the production of IFN-γ induced by IL-18 on mRNA and protein levels via NF-κB as well as p38 and JNK MAPK activation. Compared to IFN-γ, TNF-α showed different behaviour in KG-1 cells. On mRNA level I found only weak induction of TNF-α by IL-18 which was potentiated in the presence of PIC. Similarly, the release of TNF-α by IL-18 plus PIC required NF-κB as well as p38 and JNK MAPK activation. Furthermore, in the present work I found that TLR-3 is required for IFN-γ and TNF-α production. In addition, it is demonstrated by immunofluoresence that TLR-3 is localized in cytoplasm but not on the cell surface in KG-1 cells. Recently, it has been demonstrated that IFN-γ shows therapeutic potential as detected in AML blasts, specifically via inhibition of proliferation and induction of apoptosis. Thus our data could serve as a rationale for the clinical use of PIC and IL-18 in combination therapy. In search for new cytokines potentially modulated by the combination IL-18 plus PIC in KG-1 cells, cytokine antibody array analysis was performed. I found an upregulation of expected genes like IP-10 but most interestingly unexpected upregulation of PDGF-AA. Searching for detailed mechanisms of PDGF-AA induction, I found that neither p38 nor JNK is involved in PDGF-AA production but NF-κB is essential for the expression of PDGF-AA. Furthermore, I found that PDGF-AA is not able to increase the proliferation of KG-1 cells. PDGF and TGF-β are examples of signaling molecules which control the growth, survival, motility, and differentiation of cells. Therefore, the release of TGF-β by IL-18 plus PIC was monitored by ELISA. The level of TGF-β in cellular supernatants revealed that neither PIC nor IL-18 was able to significantly mediate release of TGF-β indicating that only PDGF-AA but not TGF-β is induced by PIC and IL-18 in KG-1 cells. To the best of our knowledge this is the first time that IL-18 or PIC is shown to induce the expression of PDGF-AA in KG-1 cells.
Resistance in glucocorticoid-induced apoptosis is associated with poor prognosis for long term survival in childhood acute lymphoblastic leukemia (ALL). As Smac mimetics have been shown to reactivate apoptosis by antagonizing Inhibitor of Apoptosis (IAP) proteins, we investigate the potential of the Smac mimetic BV6 to overcome glucocorticoid-resistance in ALL. This study shows that BV6 synergistically cooperates with glucocorticoids to trigger apoptosis and to suppress clonogenic growth of pediatric ALL cells. Of note, the BV6/glucocorticoid combination treatment also induces cell death in cells having defects in the apoptotic signaling cascade by inducing a switch from apoptotic to necroptotic cell death. The clinical relevance of our novel combination treatment is underscored by parallel experiments in primary pediatric ALL samples, in which glucocorticoids and BV6 act together to induce cell death in a synergistic manner. Importantly, the addition of BV6 enhances the anti-leukemic effects of glucocorticoids in an in vivo mouse model of pediatric ALL without causing substantial side effects, highlighting the potency of a BV6/glucocorticoid combination treatment. In contrast, BV6 does not increase cytotoxicity of glucocorticoids against several non-malignant cell types of the lympho-hematopoietic system. Furthermore, we have identified the novel underlying mechanism of BV6/glucocorticoid-induced apoptosis by showing that BV6 and glucocorticoids synergistically act together to promote assembly of the ripoptosome, a RIP1/FADD/caspase-8-containing cell death complex. Ripoptosome assembly is critically required for BV6/Dexamethasone-induced cell death, since genetic silencing of its members, i.e. RIP1, reduces ROS production, caspase activation and most importantly cell death induction. BV6/glucocorticoid combination treatment promotes ripoptosome assembly by inhibition of both of its negative regulators, IAP proteins and cFLIP. Thus, we identify that BV6 and glucocorticoids cooperate together to reduce cIAP1, cIAP2 and XIAP protein levels and cFLIP expression. Ripoptosome formation occurs independently of autocrine/paracrine loops of death receptor ligands, since blocking antibodies for TNFα, TRAIL or CD95L or genetic silencing of their corresponding receptors fail to rescue BV6/glucocorticoid-induced cell death. In summary, this study shows that the Smac mimetic BV6 sensitizes for glucocorticoid-induced apoptosis by promoting ripoptosome assembly with important implications for the treatment of childhood ALL.
Alzheimer’s Disease (AD) is the most common neurodegenerative disorder marked by progressive loss of memory and cognitive ability. The pathology of AD is characterised by the presence of amyloid plaques, intracellular neurofibrillary tangles and pronounced cell death. The aim of this thesis was to investigate pathways involved in the Aß cascade of neurodegeneration. Since novel findings indicate that already this Aß species exerts neurotoxic effects long before hyperphosphorylated tau, neurofibrillary tangles and extracellular Aß plaques appear, the investigations were accomplished with specific regard to the effects of intracellular Aß. The Swedish double mutation in the APP gene results in six- to eightfold increased Aß production of both Aß1-40 and Aß1-42 compared to human wildtype APP cells (APPwt). Data obtained from PC12 cells indicate that it is possible to specifically increase the Aß load without enhancing APP expression levels. On the basis of these findings, it seemed possible to investigate dose-dependent effects of Aß in multiple experimental designs. These assay designs were created in order to mimick different in-vivo situations that are discussed to occur in AD patients: APPsw PC12 cells exhibit low physiological concentrations of Aß within picomolar range in contrast to APPsw HEK cells, expressing Aß levels within the nanomolar range. Of note, the APPsw HEK cells showed a specific and highly significant increase in the intracellular accumulation of insoluble Aß1-42. Moreover, an intracellular accumulation of Aß and APP was found in the mitochondria of the HEK APPsw cells suggesting a direct impact on mitochondrial function on these cells. This effect might finally lead to disturbances in the energy metabolism of the cell or to increased cell death. Furthermore, baseline g- and ß-secretase activity was assessed since these enzymes represent promising therapeutic targets to slow or halt the disease process. As expected, ß-secretase activity was significantly elevated in all APPsw cell lines. This might be due to the proximity of the Swedish double mutation next to the N-terminus of the Aß sequence. Interestingly, g-secretase activity was similarly increased in PC12 APPsw cells. In addition, the toxicity of different Aß species was investigated in SY5Y and PC12 cells with regard to their effect on cellular viability mirrored by mitochondrial activity using MTT assay. Here, it turned out that not monomers, but already dimers are neurotoxic correlates. Fibrillar Aß species showed the highest toxicity. In the next step, SY5Y cells forming endogenous, dimeric APP and Aß were investigated. In accordance with previous findings, these cells showed a decreased MTT reduction potential in comparison to APPwt and control SY5Y cells reflecting a decrease of cellular viability. The impaired energy metabolism of the cells was even more drastically mirrored by reduced baseline ATP levels. In the second part of this thesis, the expression and intracellular distribution of Bcl-2 family proteins and pro-apoptotic mitochondrial factors under baseline conditions and during oxidative stress were analyzed in the APPwt and APPsw bearing cells. The most prominent finding was the reduction of expression levels of the anti-apoptotic factor Bcl-xL in the cytosolic fractions of APPwt and APPsw PC12 cells. This might indicate that a lack of anti-apoptotic factors or their altered intracellular distribution, rather than an increase in caspase-dependent pro-apoptotic factors, could be responsible for the increased vulnerability of APPwt- and APPsw-transfected PC12 cells against oxidative stress. Since total Bcl-xL expression was unaffected in PC12 cells, in contrast to APPwt and APPsw-expressing SY5Y and HEK cells revealing significantly decreased Bcl-xL expression levels. Thus, alterations in Bcl-xL distribution seem to be an early event in the disease process. Increasing Bcl-xL expression might potentially be one promising strategy for AD modification. PC12 and HEK cells bearing APPsw or APPwt were treated with the potent g-secretase inhibitor DAPT. Of note, DAPT did not only efficiently block Aß production, but additionally led to an elevation of the MTT reduction potential, reflecting an increase in cellular viability. As another disease-modifying strategy, several efforts are undertaken to ameliorate AD-relevant symptoms by the treatment with nerve growth factor (NGF). Generally, it is known that substituted pyrimidines have modest growth-promoting effects. Here, KP544, a novel substituted pyrimidine, was characterised. This drug increased MTT reduction potential in terminally differentiated and undifferentiated PC12 cells. Furthermore, treatment with KP544 led to a reduction in Aß1-40 secretion. Thus, one may conclude that the target of KP544, GSK-3ß, represents a connecting link between the two main pathological hallmarks of AD and might thus be a very promising therapeutic target for AD.