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The chemopreventive and anticancer effects of resveratrol (RSV) are widely reported in the literature. Specifically, mechanisms involving epigenetic regulation are promising targets to regulate tumor development. Bromodomains act as epigenetic readers by recognizing lysine acetylation on histone tails and boosting gene expression in order to regulate tissue-specific transcription. In this work, we showed that RSV is a pan-BET inhibitor. Using Differential Scanning Fluorimetry (DSF), we showed that RSV at 100 µM increased the melting temperature (∆Tm) of BET bromodomains by around 2.0 °C. The micromolar dissociation constant (Kd) range was characterized using Isothermal Titration Calorimetry (ITC). The RSV Kd value accounted to 6.6 µM in case of BRD4(1). Molecular docking proposed the binding mode of RSV against BRD4(1) mimicking the acetyl-lysine interactions. All these results suggest that RSV can also recognize epigenetic readers domains by interacting with BET bromodomains.
Binding free energy calculations that make use of alchemical pathways are becoming increasingly feasible thanks to advances in hardware and algorithms. Although relative binding free energy (RBFE) calculations are starting to find widespread use, absolute binding free energy (ABFE) calculations are still being explored mainly in academic settings due to the high computational requirements and still uncertain predictive value. However, in some drug design scenarios, RBFE calculations are not applicable and ABFE calculations could provide an alternative. Computationally cheaper end-point calculations in implicit solvent, such as molecular mechanics Poisson–Boltzmann surface area (MMPBSA) calculations, could too be used if one is primarily interested in a relative ranking of affinities. Here, we compare MMPBSA calculations to previously performed absolute alchemical free energy calculations in their ability to correlate with experimental binding free energies for three sets of bromodomain–inhibitor pairs. Different MMPBSA approaches have been considered, including a standard single-trajectory protocol, a protocol that includes a binding entropy estimate, and protocols that take into account the ligand hydration shell. Despite the improvements observed with the latter two MMPBSA approaches, ABFE calculations were found to be overall superior in obtaining correlation with experimental affinities for the test cases considered. A difference in weighted average Pearson () and Spearman () correlations of 0.25 and 0.31 was observed when using a standard single-trajectory MMPBSA setup ( = 0.64 and = 0.66 for ABFE; = 0.39 and = 0.35 for MMPBSA). The best performing MMPBSA protocols returned weighted average Pearson and Spearman correlations that were about 0.1 inferior to ABFE calculations: = 0.55 and = 0.56 when including an entropy estimate, and = 0.53 and = 0.55 when including explicit water molecules. Overall, the study suggests that ABFE calculations are indeed the more accurate approach, yet there is also value in MMPBSA calculations considering the lower compute requirements, and if agreement to experimental affinities in absolute terms is not of interest. Moreover, for the specific protein–ligand systems considered in this study, we find that including an explicit ligand hydration shell or a binding entropy estimate in the MMPBSA calculations resulted in significant performance improvements at a negligible computational cost.
Alzheimer’s disease is a chronic neurodegenerative disease that causes problems with memory, thinking and behavior. The pathophysiological hallmarks of AD are extracellular senile plaques and intracellular neurofibrillary tangles. Amyloid plaques mainly contain the amyloid-β (Aβ) peptide, which appears as a cleavage product of the APP. APP is a type I transmembrane protein with a large extracellular domain and a short cytoplasmic tail. It is expressed in variety of tissues e.g. in neuronal tissue (brain, spinal cord, retina), and non-neuronal tissues (kidney, lung, pancreas, prostate gland, and thyroid gland) (Dawkins and Small, 2014). APP has been studied because of its link to AD, however, its role in normal brain function is poorly understood. APP is processed by two different pathways, amyloidogenic pathway and non-amyloidogenic pathway. In physiological condition, the majority of APP is processed via the non-amyloidogenic, thus leading to the generation of the secreted N-terminal APP processing product sAPPα. sAPPα is formed due to the cleavage of APP by α-secretase. In previous studies, our group has shown that sAPPα produce potent neuroprotective effect by altering gene expression, as well as by antagonizing several different types of neurotoxic stress stimuli (Copanaki et al., 2010; Kögel et al., 2003, 2005; Milosch et al., 2014). Several studies have shown that protein degradation is reduced in AD (Hong et al., 2014; Lipinski et al., 2010) but the role of APP and its cleavage products in protein degradation is still unknown. This thesis discusses about the physiological functions of APP in neuroprotection and protein homeostasis.
In the first part of the thesis (Section 4.1 - 4.4), the neuroprotective properties of yeast derived sAPPα and E1 (N-terminal domain of sAPPα) were investigated under serum and glucose deprivation conditions. In previous work, it was shown that recombinant sAPPα evoked a significant decrease in serum deprivation triggered cell death in human SH-SY5Y neuroblastoma cells and mouse embryonic fibroblast MEF cells. It was also observed that sAPPα induces the phosphorylation of Akt which leads to neuroprotection (Milosch et al., 2014). This study investigated whether this neuroprotection is associated with altered expression of downstream intracellular Akt targets such as FoxO, Bim, Bcl-xL and Mcl-1 under stress conditions. Here it was shown that sAPPα prevents activation and nuclear translocation of FoxO. FoxO act as a transcription factor for different proapoptotic genes such as Bim. It was also observed that Bim protein and mRNA expression was significantly reduced with sAPPα and E1 treatment. The expression of antiapoptotic protiens such as Bcl-xL and Mcl-1 were also examined and it was observed that sAPPα and E1 increases expression of both these proteins. Furthermore, it was previously demonstrated that uncleaved holo-APP functionally cooperates with sAPPα to activate Akt and provide neuroprotection (Milosch et al., 2014). Therefore, to investigate the function of the APP in sAPPα regulated Akt downstream proteins expressions, MEF APP KO cells were used. E1 and sAPPα only showed neuroprotective modulatory effect on these Akt downstream targets in MEF wt cells, but not in APP KO cells. In addition, sAPPα also showed neuroprotection in primary wt hippocampal neurons under trophic factor deprivation. Cellular fractionation experiments were also done to determine the role of sAPPα in cytochrome c release from mitochondria. It was observed that sAPPα treatment can inhibit mitochondrial cytochrome c release in wt MEF cells.
The second part of the thesis (Section 4.5 - 4.9) discusses about the role of sAPPα in protein homeostasis. It was observed that sAPPα prevents proteotoxic stress induced BAG3 protein expression in SH-SY5Y and MEF cells. This was also observed in mRNA levels which indicate a transcriptional regulation. Furthermore, treatment with sAPPα was also shown to decrease aggresomes formation. Aggresomes are perinuclear aggregates which are formed due to accumulation of damaged and misfolded proteins and BAG3 plays important role in their formation and the transport of degradation prone proteins into these structures. The analysis of proteasomal activity showed a reduced accumulation of proteasomal substrate d2 by sAPPα under proteasomal stress. In proteasomal activity assay, sAPPα was shown to increase the degradation of proteasomal substrate SUC-LLVY-AMC and the fluorigenic signal was measured spectrophotometrically. The sAPPβ fragment which is generated via the amyloidogenic pathway was also examined for its role in BAG3 expression and proteasomal degradation. sAPPβ, which has almost similar structure as sAPPα, only 17 amino acids at the C-terminus is missing, was failed to modulate BAG3 expression and proteostasis. This indicates that these biological effects are highly specific for sAPPα.
...
Bromodomain-containing protein 4 (BRD4) is a member of the bromo- and extraterminal (BET) domain-containing family of epigenetic readers which is under intensive investigation as a target for anti-tumor therapy. BRD4 plays a central role in promoting the expression of select subsets of genes including many driven by oncogenic transcription factors and signaling pathways. However, the role of BRD4 and the effects of BET inhibitors in non-transformed cells remain mostly unclear. We demonstrate that BRD4 is required for the maintenance of a basal epithelial phenotype by regulating the expression of epithelial-specific genes including TP63 and Grainy Head-like transcription factor-3 (GRHL3) in non-transformed basal-like mammary epithelial cells. Moreover, BRD4 occupancy correlates with enhancer activity and enhancer RNA (eRNA) transcription. Motif analyses of cell context-specific BRD4-enriched regions predicted the involvement of FOXO transcription factors. Consistently, activation of FOXO1 function via inhibition of EGFR-AKT signaling promoted the expression of TP63 and GRHL3. Moreover, activation of Src kinase signaling and FOXO1 inhibition decreased the expression of FOXO/BRD4 target genes. Together, our findings support a function for BRD4 in promoting basal mammary cell epithelial differentiation, at least in part, by regulating FOXO factor function on enhancers to activate TP63 and GRHL3 expression.
Protein kinases are highly tractable targets for drug discovery. However, the biological function and therapeutic potential of the majority of the 500+ human protein kinases remains unknown. We have developed physical and virtual collections of small molecule inhibitors, which we call chemogenomic sets, that are designed to inhibit the catalytic function of almost half the human protein kinases. In this manuscript we share our progress towards generation of a comprehensive kinase chemogenomic set (KCGS), release kinome profiling data of a large inhibitor set (Published Kinase Inhibitor Set 2 (PKIS2)), and outline a process through which the community can openly collaborate to create a KCGS that probes the full complement of human protein kinases.
Die 5-LO ist ein Schlüsselenzym der LT-Biosynthese. Sie katalysiert in einem ersten Schritt zunächst die Umsetzung freigesetzter AA zu 5-HPETE und wandelt diese anschließend in LTA4 um. LT sind starke Entzündungsmediatoren, die an entzündlichen und allergischen Reaktionen des Körpers beteiligt sind. Sie lösen eine Immunantwort aus und können zur Entstehung von Asthma bronchiale, allergischer Rhinitis, Herz-Kreislauf-Erkrankungen und verschiedenen Krebserkrankungen beitragen [28]. NFS gehören zur Klasse der michaelreaktiven Verbindungen und inhibieren die 5-LO durch Interaktion mit katalytisch aktiven Cysteinresten in der Nähe der Substrateintrittspforte. Diese Tatsache macht michaelreaktive Verbindungen innerhalb der Entzündungsforschung zu einer interessanten Substanzklasse. Michaelreaktive Verbindungen besitzen eine durch Elektronenzug aktivierte Doppelbindung. Hierdurch verfügen diese Wirkstoffe über elekrophile Eigenschaften, wodurch sie leicht mit Nukleophilen reagieren können. Cysteine bestehen aus nukleophilen Thiolgruppen, die mit einer positiv polarisierten Doppelbindung, wie sie in michaelreaktiven Verbindungen vorliegt, reagieren können. Diese Tatsache kann sie zu effektiven und nachhaltigen Enzymaktivitätsmodulatoren machen. In dieser Arbeit wurde eine große Bandbreite verschiedenster michaelreaktiver Verbindungen auf ihre Fähigkeit untersucht, die 5-LO über Michael-Addition an ihren Cysteinen zu inhibieren. Zum einen wurden Pflanzeninhaltsstoffe mit antiinflammatorischen Eigenschaften, zugelassenene Wirkstoffe mit Michael-Akzeptorfunktion und zum anderen Verbindungen, die durch gezielte Struktursuche ausgewählt wurden, untersucht. Die Testung verschiedenster Strukturen sollte Aufschluss über strukturelle Voraussetzungen für die 5-LO-Inhibition durch Interaktion mit Cysteinen liefern. Hierfür wurden die Substanzen zunächst im intakten Zellsystem und schließlich am aufgereinigten Enzym (r5LO-wt) auf ihre 5-LO-inhibierenden Eigenschaften untersucht. Nachfolgende Messungen an r5LO-4C, deren vier prominente Cysteine durch Serin mutiert wurden, zeigten an, ob die Inhibition der 5-LO-Produktbildung cysteinabhängig war. Die hierbei erhaltenen Ergebnisse deuten darauf hin, dass ganz bestimmte strukturelle Eigenschaften des Michael-Akzeptors, Voraussetzung für eine Interaktion mit den Cysteinen der 5-LO sind. Vor allem Verbindungen mit chinoidem Grundgerüst stellten sich als thiolreaktive Verbindungen heraus, die die 5-LO hauptsächlich über Interaktion mit ihren Cysteinen inhibierten. Weiterhin zeigten die erhaltenen Ergebnisse, dass die strukturelle Umgebung um die aktivierte Doppelbindung des Michael-Akzeptors enorme Auswirkungen auf die Thiolreaktivität hatte. TQ hemmte die 5-LO hauptsächlich über Interaktion mit Cysteinen, wohingegen die 5-LO-Inhibition durch Embelin unabhängig von Cysteinen zu sein schien. Eine daraufhin durchgeführte MALDI-MS-Analyse bestätigte die Bindung von NAPQI und TQ an die Cysteine 416 und 418. Durch diese Arbeit konnte erstmals gezeigt werden, dass eine Reihe antiinflammatorisch wirksamer, natürlich vorkommender Verbindungen wie TQ, Plumbagin, Primin und auch synthetisch generierte Verbindungen wie AA861, CDDO, Methyl-BQ, Methoxy-BQ, Methoxy-Nitrostyren, NAPQI und OH-BQ die 5-LO über Interaktion mit ihren Cysteinen inhibieren.
Serine/arginine-protein kinase 1 (SRPK1) regulates alternative splicing of VEGF-A to pro-angiogenic isoforms and SRPK1 inhibition can restore the balance of pro/antiangiogenic isoforms to normal physiological levels. The lack of potency and selectivity of available compounds has limited development of SRPK1 inhibitors, with the control of alternative splicing by splicing factor-specific kinases yet to be translated. We present here compounds that occupy a binding pocket created by the unique helical insert of SRPK1, and trigger a backbone flip in the hinge region, that results in potent (<10 nM) and selective inhibition of SRPK1 kinase activity. Treatment with these inhibitors inhibited SRPK1 activity and phosphorylation of serine/arginine splicing factor 1 (SRSF1), resulting in alternative splicing of VEGF-A from pro-angiogenic to antiangiogenic isoforms. This property resulted in potent inhibition of blood vessel growth in models of choroidal angiogenesis in vivo. This work identifies tool compounds for splice isoform selective targeting of pro-angiogenic VEGF, which may lead to new therapeutic strategies for a diversity of diseases where dysfunctional splicing drives disease development.
Drug product performance testing is an important part of quality-by-design approaches, but this process often lacks the underlying mechanistic understanding of the complex interactions between the disintegration and dissolution processes involved. Whereas a recent draft guideline by the US Food and Drug Administration (FDA) has allowed the replacement of dissolution testing with disintegration testing, the mentioned criteria are not globally accepted. This study provides scientific justification for using disintegration testing rather than dissolution testing as a quality control method for certain immediate release (IR) formulations. A mechanistic approach, which is beyond the current FDA criteria, is presented. Dissolution testing via United States Pharmacopeial Convention Apparatus II at various paddle speeds was performed for immediate and extended release formulations of metronidazole. Dissolution profile fitting via DDSolver and dissolution profile predictions via DDDPlus™ were performed. The results showed that Fickian diffusion and drug particle properties (DPP) were responsible for the dissolution of the IR tablets, and that formulation factors (eg, coning) impacted dissolution only at lower rotation speeds. Dissolution was completely formulation controlled if extended release tablets were tested and DPP were not important. To demonstrate that disintegration is the most important dosage form attribute when dissolution is DPP controlled, disintegration, intrinsic dissolution and dissolution testing were performed in conventional and disintegration impacting media (DIM). Tablet disintegration was affected by DIM and model fitting to the Korsmeyer–Peppas equation showed a growing effect of the formulation in DIM. DDDPlus was able to predict tablet dissolution and the intrinsic dissolution profiles in conventional media and DIM. The study showed that disintegration has to occur before DPP-dependent dissolution can happen. The study suggests that disintegration can be used as performance test of rapidly disintegrating tablets beyond the FDA criteria. The scientific criteria and justification is that dissolution has to be DPP dependent, originated from active pharmaceutical ingredient characteristics and formulations factors have to be negligible.
Human MSCs are currently deployed in a wide range of clinical applications and disease models, because of their regenerative and immune modulatory potential. Unfortunately, the fate of MSCs after systemic administration and the related interactions within the blood circulation are still not fully understood. The majority of i.v. or i.a administered MSCs accumulate in the lungs and loose traceability after 3-4 days in vivo144. Since engraftment rate and long term persistence of injected MSCs seems rather low, we tried to improve in vivo kinetics by using hyperosmolaric injection media (HyperHAES) in order to describe the impact on biodistribution, cell morphology and survival rate. In vitro culture related changes in morphology and surface expression patterns were analysed using flow cytometry and brightfield morphology scan in correlation with calibrated microbeads. In vivo tracking of male PKH67 labeled human MSCs in an immunecompetent mouse model were achieved using SRY-gene qRT-PCR analysis and flow cytometry/fluorescence microscopy at different time points. Kinetics, viability and cell-cell interaction of HyperHAES coinjected MSCs in comparison to NaCl 0.9% injection media were assessed with a combination of altering mitochondrial membrane potential (MMP), caspase 3/7-activity, additional survival and surface markers. Incubation of human MSCs in hyperosmolaric injection media (HyperHAES) shortly before i.v. injection decreased average diameter of culture expanded MSCs about 30% (from 48.7±2.29μm to 34.6±2.04μm) and improved viability and retrieval rate of injected MSCs within 24h. HyperHAES decreased significantly the loss of MMP and the signal intensity of the dead cell marker PI in comparison to isotonic control. HyperHAES treated MSCs are detected at higher frequencies in most murine tissues but didn`t result in alterations of interaction with the host immune system or caspase activation. Additionally, HyperHAES seemed to enable MSCs to reach organs with smaller microcirculation like the spleen. Functional impairment of MSC in HyperHAES was analysed with Phalloidin A staining for cytoskeletal activation and showed no signs of disturbed actin polymerization, whereas nuisance of migration and immunemodulatory characteristics were not addressed. PKH67 labeled MSCs decrease in size after i.v. injection in mice, acquire apoptotic and phagocytic cell markers, and accumulate in lungs and liver. This process could be delayed but not reverted by preincubation of MSCs in HyperHAES. Our findings help to explain the rapid loss of traceable MSCs after systemic delivery.
To understand neurodegenerative diseases is one of the major challenges of the 21st century. This also includes Alzheimer´s disease (AD), which represents a chronic neurodegenerative disorder, with long preclinical and prodromal phases (approx. 20 years) and an average clinical duration of 8–10 years. In the early phase of this disease, patients show deterioration of memory, difficulties in finding the right words for everyday objects or mood swings. The risk of AD grows exponentially with age, doubling approximately every 5 to 6 years. AD may contribute to 60–70% of all dementia cases, being the most common cause of this disease. Dementia is one of the major causes of disability and dependency among older people worldwide. The causes of the sporadic form of AD with late onset (LOAD) are not yet known, but it seems to be a result of multiple factors. Neuropathological features are extracellular senile plaques, containing beta-amyloid peptides (Aβ) and intracellular neurofibrillary tangles, containing paired helical tau proteins, which have been associated with neuronal loss and atrophy of the cerebral cortex. Thus, misfolded proteins seem to contribute to the pathogenesis, but are not the only players in the disease process. Developing feasible therapies is difficult due to the multifactorial pathology of AD. Currently approved drugs only attenuate symptoms, but do not cure the disease. Research into AD also has had several failures in terms of developing disease-modifying therapies. Thus, new therapeutic targets in order to develop a causal therapy are desperately needed. Since AD starts many years far before the first symptoms occur, new scientific approaches focus on the early stage, which are discussed to be important in aging and the onset of AD. Today, the hypothesis of the advanced mitochondrial cascade becomes more and more the leading model for LOAD, integrating physiological aging as the main risk factor. Thus, new interventions targeting mitochondrial dysfunction are of substantial interest. Accordingly, the efficacy of Dimebon and TRO19622 to ameliorate mitochondrial dysfunction in cellular and murine models of AD were investigated. Dimebon (Latrepirdine) was, originally developed in Russia as an H1-antiallergic drug. It might specifically interfere with mechanisms relevant for the cognitive decline, especially by improving impaired mitochondrial function and/or dynamics in AD. TRO19622 (Olesoxim) has been identified in a phenotypic screening approach to promote the survival of primary motor neurons. Olesoxim is easily absorbed by cells and accumulates in mitochondria. Olesoxim’s mode of action is not fully understood, however it has been shown to modulate mitochondrial membranes and interact with the voltage-dependent anion channel (VDAC) and the translocator protein (TSPO; also known as PBR). Thereby it inhibits mitochondrial permeability transition. In this study, the effects of Aβ overproduction on mitochondrial function were investigated. The effects of Dimebon and Olesoxim were examined, using a HEK cell line stably transfected with the Swedish APP double mutation (HEKsw) and un-transfected control cells (HEKut). Mitochondrial membrane potential, ATP concentrations, and respirometry were measured. Western Blot analysis of marker proteins for fission & fusion, autophagy, mitogenesis and mPTP formation were performed. Confocal laser scanning microscopy was introduced as a novel method to visualize mitochondrial dynamics. Olesoxim was also tested in Thy-1-C57BJ/6-APPSL mice representing a murine model of AD. For the in vivo model mitochondria from brain tissue were isolated and dissociated brain cells were prepared to determine respiration, lipid peroxidation, MMP, and ATP-levels. Both, the in vitro and in vivo models were compared and discussed in relation to human post-mortem data. The research was conducted in frame of the EU-project entitled „MITOTARGET“ (Mitochondrial dysfunction in neurodegenerative diseases: towards new therapeutics) funded under FP7-Health (http://cordis.europa.eu/result/rcn/54471_en.html). HEKsw cells showed an overall reduction in the mitochondrial respiration, a significant lower MMP, and significantly reduced ATP levels compared to HEKut cells. Mitochondrial mass was equal in both cell lines. In addition most mitochondria in HEKsw cells showed truncated morphology, followed by punctuated mitochondria. Levels of the fission related protein Drp were significantly elevated in HEKsw cells whereas protein levels of fusion related OPA were strongly reduced, leading to a shift in the distribution pattern towards shorter mitochondria. Moreover, HEKsw cells showed reduced mitochondrial density. Protein levels of the translocase of the inner mitochondrial membrane (TIMM50) were strongly diminished in HEKsw cells. The OXPHOS machinery is located in the inner membrane, where the MMP is build up and ATP is generated. Reduced TIMM50 levels in HEKsw indicated a reduction of the inner mitochondrial membrane, which could explain the described deficits in OXPHOS, MMP, ATP and mitochondrial morphology and density. Concentration of both mPTP markers, the voltage-depended anion channel (VDAC) and the peripheral benzodiazepine receptor (PBR), were broadly increased in HEKsw cells. Thy1-APPSL transgenic mice were characterized as in vivo model of AD. Those mice are modified to express the human form of APP, containing both, the Swedish (KM670/671NL) and the London (V717L) double mutations under the murine Thy1 promotor. Beginning at the age of 3 months, Thy1-APPSL mice develop elevated Aβ levels and mitochondrial dysfunction. Mitochondria isolated from brains of Thy-1-C57BJ/6-APPSL mice showed significant impaired respiration, resulting in a reduced MMP. However, ATP levels in dissociated brain cells did not differ compared to controls. Protein levels of FIS were unchanged, whereas Drp levels were significantly increased. Levels of the mitochondrial fusion marker optic atrophie-1 (Opa) protein were significantly reduced. Peroxisome proliferation-activated receptor gamma coactivator 1-alpha (PGC1) is a transcription factor, which represents a master regulator of mitochondrial biogenesis. PGC1 expression was significantly elevated in brains of Thy-1-C57BJ/6-APPSL mice. However, mitochondrial mass seemed to be equal in both mouse lines. Both LC3-Isoforms, the cytosolic and the autophagosomal form, were not changed in brains of Thy-1-C57BJ/6-APPSL mice, which indicates equal mitophagic activity. In brain homogenates, isolated from Thy-1-C57BJ/6-APPSL mice, both mPTP marker, VDAC and PBR, were considerably increased, which is in accordance with the findings in HEKsw cells. In conclusion, both, the cellular (HEKsw) and the animal model of AD (Thy1-APPSL) broadly match pathophysiological features, which have been found in post-mortem samples from AD patients. Thus, HEKsw cells and Thy1-APPSL mice seem to be suitable models to study new treatments against AD. Incubation of HEKsw cells with Dimebon resulted in a remarkable increase in respiratory activity and restored the MMP after impairing the cells with rotenon. Dimebon had no effects on ATP levels in both cell lines, neither after challenging cells with rotenon, nor under basal conditions. By adding Dimebon, citrate synthase (CS) activity in HEKsw cells was increased and mitochondrial morphology was shifted to a tubular shape. Dimebon further enhanced protein levels of Drp and resulted in the compensation of reduced OPA levels. Moreover, Dimebon restored the increased expression levels of the mPTP markers VDAC and PBR. Aβ1-40 levels were significantly decreased in HEKsw cells. However, changes in Aβ1-40 levels seemed to be too small, to solely explain the much larger effects of Dimebon on impaired mitochondrial function. In conclusion, Dimebon treatment restored diverse defects in Aβ overexpressing cells: Aβ levels were reduced, autophagy marker were increased, mitophagy as repair and renewal mechanism was elevated, mitochondrial mass and density were increased, OXPHOS capacity was restored, mitochondrial dynamics were balanced, mitochondrial shape showed a normal distribution, expression levels of the mPTP constituents were reduced, TIMM50 levels augmented to control levels and stress induced MMP and ROS levels were reduced. All these effects were observed after incubation of cells with a rather low concentration of 100 nmol/L. Based on these findings and in addition to already existing literature, Dimebon presents a potential therapeutic option for diseases with accompanied mitochondrial dysfunction. Although, clinical findings published so far are inconsistent. Olesoxim induced a general increase in respiratory activity and enhanced the electron transport (ETS) capacity in HEKsw cells. In addition it normalized the OXPHOS activity almost to control levels. However, incubation using different Olesoxim concentrations led to a dose independent decline in the MMP and decreased ATP levels. Adding Olesoxim caused a dose-dependent change in the length of mitochondria strongly shifting the pattern towards longer mitochondria. In HEKsw cells a reduced mitochondrial density was observed which was reversed by Olesoxim dose-dependently. Olesoxim completely compensated the severely reduced expression levels of TIMM50, but had no effects on TOMM22 levels. An unexpected finding was that 10 µM Olesoxim significantly increased Aβ1-40 levels. Effects of Olesoxim were also tested in vivo. Treatment of Thy-1-C57BJ/6-APPSL mice with Olesoxim restored the impaired MMP in dissociated brain cells, but had no effects on ATP-levels. Olesoxim increased the respiratory activity in isolated brain mitochondria and restored impaired respiration complex activities almost to control levels, without having an effect on CS activity. However, treatment with Olesoxim caused an increase of PGC1 protein levels in brains of Thy-1-C57BJ/6-APPSL mice,beyond basal levels of littermate controls. The mPTP marker proteins voltage-depended anion channel (VDAC) and peripheral benzodiazepine receptor (PBR) were significantly reduced. As well as in the cell models, treatment of Thy-1-C57 BJ/6-APPSL mice with Olesoxim significantly enhanced total human, soluble human and soluble mouse Aβ1-40 levels. Further investigation needs the observation that Olesoxim caused partly negative effects in controls. For instance, Olesoxim reduced the OXPHOS capacity and enhanced protein levels of VADAC and PBR in brains of C57BJ/6 littermate control mice, which could limit the applicability of Olesoxim in further preclinical studies.
The arachidonic acid cascade is a key player in inflammation, and numerous well-established drugs interfere with this pathway. Previous studies have suggested that simultaneous inhibition of 5-lipoxygenase (5-LO) and soluble epoxide hydrolase (sEH) results in synergistic anti-inflammatory effects. In this study, a novel prototype of a dual 5-LO/sEH inhibitor KM55 was rationally designed and synthesized. KM55 was evaluated in enzyme activity assays with recombinant enzymes. Furthermore, activity of KM55 in human whole blood and endothelial cells was investigated. KM55 potently inhibited both enzymes in vitro and attenuated the formation of leukotrienes in human whole blood. KM55 was also tested in a cell function-based assay. The compound significantly inhibited the LPS-induced adhesion of leukocytes to endothelial cells by blocking leukocyte activation.
Background: The oral administration of the gum resin extracts of Indian frankincense (Boswellia serrata Roxb. ex Colebr) results in very low plasma concentrations of boswellic acids (BAs), being far below the pharmacologically active concentrations required in vitro for anti-inflammatory activity. For that reason the use of Indian frankincense in clinical practice and pharmaceutical development has substantially lagged behind. Recently the application of new formulation technologies resulted in a formulation of frankincense extract with lecithin, which revealed improved absorption and tissue penetration of BAs in a rodent study, leading for the first time to plasma concentrations of BAs in the range of their anti-inflammatory activity.
Purpose: In order to verify these encouraging results in humans, the absorption of a standardized Boswellia serrata extract (BE) and its lecithin formulation (CSP) was comparatively investigated in healthy volunteers.
Study design: According to a randomized cross-over design with two treatments, two sequences and two periods, 12 volunteers alternatively received the lecithin-formulated Boswellia extract (CSP) or the non-formulated Boswellia extract (BE) at a dosage of 2 × 250 mg capsules.
Methods: The plasma concentrations of the six major BAs (KBA, AKBA, βBA, αBA, AβBA, AαBA) were determined using LC/MS.
Results: With the exception of KBA, a significantly higher (both in terms of weight-to-weight and molar comparison) and quicker absorption of BAs from the lecithin formulation was observed, leading to Cmax in the range required for the interaction with their molecular targets.
Conclusion: These findings pave the way to further studies evaluating the clinical potential of BAs, and verify the beneficial effect of lecithin formulation to improve the absorption of poorly soluble phytochemicals.
Curcumin, the active constituent of Curcuma longa L. (family Zingiberaceae), has gained increasing interest because of its anti-cancer, anti-inflammatory, anti-diabetic, and anti-rheumatic properties associated with good tolerability and safety up to very high doses of 12 g. Nanoscaled micellar formulations on the base of Tween 80 represent a promising strategy to overcome its low oral bioavailability. We therefore aimed to investigate the uptake and transepithelial transport of native curcumin (CUR) vs. a nanoscaled micellar formulation (Sol-CUR) in a Caco-2 cell model. Sol-CUR afforded a higher flux than CUR (39.23 vs. 4.98 μg min−1 cm−2, respectively). This resulted in a higher Papp value of 2.11 × 10−6 cm/s for Sol-CUR compared to a Papp value of 0.56 × 10−6 cm/s for CUR. Accordingly a nearly 9.5 fold higher amount of curcumin was detected on the basolateral side at the end of the transport experiments after 180 min with Sol-CUR compared to CUR. The determined 3.8-fold improvement in the permeability of curcumin is in agreement with an up to 185-fold increase in the AUC of curcumin observed in humans following the oral administration of the nanoscaled micellar formulation compared to native curcumin. The present study demonstrates that the enhanced oral bioavailability of micellar curcumin formulations is likely a result of enhanced absorption into and increased transport through small intestinal epithelial cells.
The humanized non-depleting anti-CD4 monoclonal antibody Tregalizumab (BT-061) is able to selectively activate the suppressive function of regulatory T cells and has been investigated up to phase 2b in clinical trials in patients suffering from rheumatoid arthritis (RA).
A pharmacokinetic-pharmacodynamic model, which is based on clinical data from RA and healthy subjects, used the cell surface CD4-down-modulation as marker of the antibodies' activity. This model surprisingly revealed a stronger effect of Tregalizumab in healthy subjects compared to RA patients. This thesis presents a series of experiments performed to understand this phenomenon.
To counteract oxidative stress, which is strongly associated with RA pathophysiology, the organism employs the small oxidoreductase thioredoxin-1 (Trx1). Therefore, augmented expression and secretion of Trx1 was seen in many studies the synovial fluid and plasma of RA patients. Moreover, the binding site of Tregalizumab is in close proximity to a disulfide bond in domain 2 (D2) of CD4, which is a known target for a reduction by Trx1. So, this thesis also evaluated the influence of Trx1 on binding of Tregalizumab to its target CD4.
With the experiments reported herein, it was possible to demonstrate that specific reduction of the D2 disulfide bond of CD4 by Trx1 led to diminished binding of Tregalizumab to recombinant human soluble CD4 (rh sCD4) and membrane-bound CD4 on T cells from a human leukemia cell line and peripheral blood mononuclear cells (PBMC). Moreover, the experiments revealed that this caused changes in the Tregalizumab-induced CD4 signalling pathway via the lymphocyte-specific protein tyrosine kinase p56Lck.
In summary, this thesis provides evidence that high Trx1 levels in RA patients compared to healthy subjects are a potential valid reason for diminished binding of Tregalizumab to CD4-positive T cells and offers an explanation for the observed decreased CD4 down-modulation in RA patients in comparison with healthy subjects. It emphasizes that binding of Tregalizumab is impaired in a particular way in RA patients.
Im Rahmen dieser Arbeit wurden Anaylsenmethoden zur Quantifizierung von Ceramiden und Prostanoiden in verschiedenen biologischen Matrices unter Verwendung von Nano-LC gekoppelt mit Tandemmassenspektrometrie entwickelt und bei diversen biologischen Fragestellungen angewendet.
Die analytische Methode zu Quantifizierung der Ceramide ermöglichte deren Bestimmung in einem Probenvolumen von 2 μL CSF. Diese neu entwickelte Methode ist die erste publizierte Nano-LC-MS/MS-Methode zur Quantifizierung der Ceramide in biologischen Proben, gleichzeitig ist es auch diejenige analytische Methode mit der höchsten Empfindlichkeit [171]. Die beschriebene Methode umfasste die Substanzen C8:0, C16:0, C18:1, C18:0, C20:0, C24:1 und C24:0 Ceramid, als interner Standard wurde C17:0 Ce-ramid verwendet. Die Probenaufarbeitung bestand in einer einfachen Proteinfällung und Verdünnung mit Methanol, die chromatografische Trennung der Analyten erfolgte mit einer RP-C8 Säule unter Verwendung eines Gradientenprogramms. Die Methode wurde anhand von FDA-Richtlinien bezüglich Linearität, Bestimmungsgrenze, Präzision, Richtigkeit und Autosampler-Stabilität validiert. Die erreichten Bestimmungsgrenzen betrugen 0,225 pg auf der Säule (2,25 pg/μL CSF) für alle Ceramide außer C24:0 Ceramid, für das der Wert von 0,75 pg auf der Säule (7,5 pg/μL CSF) ermittelt wurde. Mit der durchgeführten Validierung wurde die Zuverlässigkeit der Methode für die Quantifizierung der Ceramide in CSF gezeigt. Mit einem Standardadditionsexperiment konnte belegt werden, dass PBS als Ersatzmatrix für CSF geeignet ist und somit die Ergebnisse der Validierung mit dotierten PBS-Proben auf CSF-Proben übertragbar sind. Das entwickelte Verfahren wurde für die Quantifizierung der Analyten in murinen CSF-Proben im Rahmen eines Projekts zur Erforschung der Rolle der Ceramide bei Multipler Sklerose angewendet. Anhand der Ergebnisse wurde die Hypothese bestätigt, dass die Konzentration von C16:0 Ceramid in CSF von EAE-Mäusen erhöht ist.
Die zweite entwickelte Nano-LC-MS/MS-Methode ermöglichte die Quantifizierung der Prostanoide PGE2, PGD2, 6-keto PGF1α, PGF2α und TXB2 in einer geringen Anzahl Immunzellen. Für eine erfolgreiche Bestimmung der Analyt-Konzentrationen waren nur 5.000 T-Zellen oder 40.000 Mastzellen erforderlich. Damit ist die beschriebene Methode geeignet für die Quantifizierung in Zellen, die durch Isolation aus tierischen Geweben oder Organen erhalten werden, ohne dass das Vereinigen mehrerer Proben erforderlich ist. Durch die Messung dieser bestimmten Zellpopulationen kann, im Unterschied zur Vermessung des gesamten Organs, eine differenziertere Analyse der Lokalisation der gemessenen Analyten erfolgen. Mittels der entwickelten Methode konnten die Prostanoide PGE2, PGD2, 6-keto PGF1α, PGF2α und TXB2 quantifiziert werden. Als interner Standard stand für jedes dieser Prostanoide ein vierfach deuteriertes Strukturanalogon zur Verfügung. Die Aufarbeitung der Immunzell-Proben erfolgte durch Flüssig-Flüssig-Extraktion mit Ethylacetat, die Chromatografie wurde mit einer RP-C8-Säule und einem Gradientenprogramm durchgeführt. Eine Validierung erfolgte für die Quantifizierung in T-Lymphozyten und Mastzellen für die Parameter Linearität, Bestimmungsgrenze, Präzision, Richtigkeit, Wiederfindung, Selektivität und Stabilität. Auch ein Standardadditionsexperiment mit beiden Matrices wurde durchgeführt. Die Bestimmungsgrenzen betrugen 75 fg auf der Säule für PGE2 und PGD2 sowie 112,5 fg für 6-keto PGF1α, PGF2α und TXB2, damit zeichnet sich die Methode durch höchste Empfindlichkeit aus. Die Me-thode wurde zur Messung der Prostanoid-Konzentration in T-Zellen, die im Rahmen eines Kontaktallergie-Modells aus dem Blut von unterschiedlich behandelten Mäusen isoliert worden waren, angewendet. Es konnte kein Unterschied in den Prostanoid-Konzentrationen in den T-Zellen sensibilisierter und nicht-sensibilisierter bzw. provozierter und nicht-provozierter Mäuse festgestellt werden. Bei einer zweiten Anwendung wurden die Prostanoide in murinen Mastzellen, die nach Zymosan-Injektion in die Hinterpfote zu verschiedenen Zeitpunkten nach dem Auslösen der Entzündung aus dem entstandenen Ödem isoliert worden waren, gemessen. Zusätzlich für diese Anwendung wurden einige Leukotriene in die Methode integriert. Es wurde festgestellt, dass die Konzentrationen von PGE2, PGD2 und PGF2α in Mastzellen nach der Injektion von Zymosan-Injektion ansteigen, wobei die gemessenen Konzentrationen für PGE2 48 Stunden nach der Injektion verglichen mit denen nach 24 Stunden, bezogen auf die anderen beiden Prostaglandine, am stärksten ansteigen. Außerdem wurde mittels der für die Immunzellen entwickelten Methode die Prostanoide in murinem Urin, humanem Plasma und humaner Tränenflüssigkeit quantifiziert.
Zusammenfassend ermöglichen die entwickelten Methoden die Analyse geringer Ana-lytkonzentrationen in sehr kleinen Probenmengen und damit eine Reduktion von Versuchstierzahlen und Kosten.
In dieser Arbeit wurde YM155 anhand eines Neuroblastom-Zellmodells bezüglich seiner antitumoralen Wirkung, sowie möglicher Resistenzmechanismen untersucht. Mit Hilfe eines Viabilitäts-‚Screenings‘ wurde eine Auswahl von 113 chemosensitiven und chemoresistenten Neuroblastomzellen auf mögliche Kreuzresistenzen gegen YM155 untersucht. Hinsichtlich der IC50 Werte gegen YM155, lagen insgesamt 74 % der untersuchten Zelllinien im therapeutisch erreichbaren Bereich von unter 50 nM. Zusätzlich wurden Neuroblastom-, Mammakarzinom- und Prostatakarzinomzellen an eine klinisch relevante YM155 Konzentration adaptiert. Diese zeigten wiederum, dass durch die Adaptierung hervorgerufene Expressionsänderung des ABC-Transporters ABCB1 und des ‚solute carrier‘ Protein SLC35F2 eine bedeutsame Rolle hinsichtlich des Resistenzmechanismus gegen YM155 spielen. Durch den Einsatz von spezifischen ABCB1-Inhibitoren, als auch durch siRNA-vermittelte Reduzierung von ABCB1 konnte eine Abhängigkeit für die Wirksamkeit YM155 von ABCB1 in Neuroblastomzellen bestätigt werden. Des Weiteren wurde in den untersuchten Zelllinien ein Zusammenhang zwischen der Wirkung von YM155 und der Expression des ‚solute carrier‘ Proteins SLC35F2 hergestellt. Dazu wurden Zellen mit verminderter SLC35F2 Expression verwendet, welche durch Transduktion mit einem für eine SLC35F2 spezifische shRNA kodierenden Vektor etabliert wurden. Dabei führte eine verminderte SLC35F2 Expression zu einer starken Minderung der Sensitivität gegen YM155. Das Zusammenspiel dieser beiden Transporter und der damit verbundene Resistenzmechanismus gegen YM155, konnte in fast allen etablierten YM155-resistenten Zelllinien (UKF-NB-3rYM15520, 22RV1rYM155300, PC-3rYM15520, HCC-1806rYM15520 und MDA-MB-231rYM15520) gezeigt werden. Wobei diese Zellen unabhängig von der Tumorentität als Resistenzmechanismus gegen YM155 entweder eine signifikant induzierte ABCB1 Expression (verstärkter YM155 Efflux) und/oder eine verminderte SLC35F2 Expression (verringerter YM155 Influx) entwickelten. Außerdem konnte mit Hilfe der p53-depletierten Zelllinie UKF-NB-3pc-p53 eine Abhängigkeit der YM155 Wirkung vom Tumorsuppressor p53 nachgewiesen werden, wobei es durch die Depletierung von p53 zu einer verminderten Sensitivität der Zellen gegen YM155 kam. Zudem kam es durch die Nutlin-3 hervorgerufene p53 Aktivierung und Akkumulierung zu einer Verstärkung der YM155 Wirkung in den untersuchten Zellen. Diese Ergebnisse deuten darauf hin, dass der p53 Status von Zellen einen Einfluss auf deren YM155 Resistenz haben kann. Da in der Behandlung von Neuroblastomen neben der Chemotherapie auch Bestrahlung eingesetzt wird, wurde zusätzlich untersucht ob eine Adaptierung von Neuroblastomzellen an YM155 zu einer verminderten Sensitivität gegen Bestrahlung führen kann. Da die im Rahmen dieser Arbeit untersuchten UKF-NB-3 Zelllinien (UKF-NB-3 und UKF-NB-3rYM15520) eine ähnliche Sensitivität gegenüber der Bestrahlung aufwiesen, konnte kein Zusammenhang zwischen einer Adaptierung an YM155 und der Ausbildung einer Bestrahlungsresistenz gezeigt werden.
Ein weiterer wichtiger Teil dieser Arbeit war es, den primären Wirkmechanismus von YM155 in Neuroblastomzellen zu untersuchen. In vorangegangenen Studien wurde die vom Hersteller beschriebene Wirkung von YM155 als Survivin-Inhibitor in Frage gestellt. Stattdessen soll der primäre Apoptose-induzierende Effekt in erster Linie durch DNA-Schäden hervorgerufen werden, während die Survivin Inhibierung lediglich darauf folgen soll. In einer zeitlichen und konzentrationsabhängigen Kinetik der YM155 Behandlung konnte in UKF-NB-3 Zellen der genaue Zeitpunkt der Survivin-Inhibierung und der Induktion der DNA-Schadensantwort ermittelt werden. Dabei konnte in der vorliegenden Arbeit gezeigt werden, dass in Neuroblastomzellen als Antwort auf die YM155 Behandlung zuerst eine Survivin-Inhibierung erfolgt, und die DNA-Schadensantwort als Folge dieser induziert wird. Darüber hinaus belegte die siRNA-vermittelte Survivin-Inhibierung in UKF-NB-3 und UKF-NB-6, dass eine fehlende Survivin Expression die DNA-Schadensantwort induziert.
Zusammenfassend konnte in dieser Arbeit erstmals in YM155 adaptierten Neuroblastomzellen der Resistenzmechanismus gegen YM155 näher untersucht werden und darüber hinaus wurde demonstriert, dass die Wirkung von YM155 in Neuroblastomzellen nicht auf die Induktion der DNA-Schadensantwort beruht, sondern primär auf die Survivin-Inhibierung zurückzuführen ist.
Eine spezifische Immuntherapie der Allergie, wie sie für die Pollen- und Bienengiftallergie angewandt wird, ist für Nahrungsmittelallergien wegen des hohen Risikos lebensbedrohlicher Nebenwirkungen und fehlender Wirksamkeit nicht etabliert. Somit bleibt vielen Nahrungsmittelallergikern nur die Vermeidung der allergieauslösenden Lebensmittel zur Prävention allergischer Reaktionen.
Neuartige Ansätze zur Immuntherapie von Allergien beschreiben unter anderem die Verwendung sogenannter hypoallergener Proteine. Diese sind meist Allergene, deren Struktur dahingehend verändert wurde, dass sie trotz intakter Immunogenität eine reduzierte IgE-Bindungseigenschaft und damit eine verminderte Allergenität aufweisen. Studien am Hauptallergen der Birke haben gezeigt, dass sowohl die Mutation von IgE relevanten Epitopen, als auch Multimerisierungen der Birkenpollenallergene zu solchen Hypoallergenen führen.
Mit dieser Arbeit sollte untersucht werden, inwieweit sich solche gezielten Mutationen und Oligomerisierungen auf die Hauptallergene von Sellerie und Karotte übertragen lassen. Ein weiterer Punkt der Studie lag darin, zu untersuchen, ob Oligomerisierung allein oder in Kombination mit Mutationen einen größeren Einfluss auf die immunogenen Eigenschaften bewirkt.
Wichtig für die Konzeption hypoallergener Proteine ist das Wissen, um wichtige IgE bindende Epitope auf Allergenen. Für das Hauptallergen aus Birke (Bet v 1) ist die exponierte P-Loop-Region als wichtiges Epitop beschrieben. Die Sellerieallergie ist in Mitteleuropa oft auf eine IgE-Kreuzreaktivität mit Bet v 1 zurückzuführen, weshalb auch das Hauptallergen aus Sellerie (Api g 1), von welchem zwei Isoformen beschrieben sind, näher im Bereich der P-Loop-Region untersucht wurde. Die in dieser Arbeit als stärker IgE bindende bestätigte Isoform Api g 1.01 zeigt allerdings genau in dieser Region eine wichtige Abweichung von Bet v 1, weshalb eine Mutante hergestellt wurde, welche in diesem Bereich dem Bet v 1 angepasst wurde. Mit Hilfe von IgE-Bindungsstudien konnte gezeigt werden, dass diese Veränderung zu einer Verstärkung der Bindung von IgE aus Seren von Birkenpollenallergikern führte, während Seren von Sellerieallergikern, die ausschließlich auf die Isoform Api g 1.01 sensibilisiert waren, eher eine unveränderte IgE-Bindung an diese Mutante zeigten. Seren von Patienten, die auf beide Isoformen sensibilisiert waren, zeigten wie die Birkenpollenallergiker eine erhöhte Reaktivität auf diese Mutante. Da die zweite Isoform, Api g 1.02, allerdings nur eine geringe Relevanz bei der Sellerieallergie spielt, kann durch die Ergebnisse mit dieser Mutante gefolgert werden, dass die P-Loop-Region für die birkenpollenassoziierte Sellerieallergie ein weniger wichtiges IgE-Epitop ist, als für das homologe Birkenpollenallergen. Die gerichtete Mutation der P-Loop-Region kann somit bei Api g 1.01 nicht als Strategie zur Herstellung hypoallergener Derivate in Betracht gezogen werden. Weiterführende Studien bezüglich der relevanten IgE-Epitope des Hauptallergens aus Sellerie sind demnach nötig.
Ein weiterer wichtiger Ansatz zur Herstellung hypoallergener Mutanten ist die Zerstörung der dreidimensionalen Struktur von allergenen Proteinen, so dass keine Konformationsepitope mehr vorhanden sind, welche hauptsächlich für die IgE-Bindung verantwortlich sind. In der Regel sind solche Proteine nicht mehr in der Lage IgE im Patientenserum zu binden, können aber in vivo eine zelluläre Immunogenität auslösen.
Dazu wurden neben den jeweiligen Isoformen der Hauptallergene von Sellerie (Api g 1) und Karotte (Dau c 1) auch 111P-Mutanten dieser Proteine rekombinant hergestellt, welche eine zerstörte Sekundärstruktur aufwiesen. Sowohl für Sellerie als auch für Karotte, waren die mutierten Proteine nicht mehr in der Lage, die jeweiligen spezifischen IgE-Antikörper in Patientenserum zu erkennen. Sie wiesen somit eine reduzierte Allergenität auf, was sie zu möglichen geeigneten Kandidaten für eine Immuntherapie machen. Wichtig für einen Mechanismus zur effektiven Immuntherapie ist aber auch die Induktion von blockierenden IgG-Antikörpern, welche unter anderem das Allergen binden und somit verhindern, dass es zu einer Kreuzvernetzung von IgE kommt, welches über den FceRI-Rezeptor auf der Oberfläche von Mastzellen gebunden ist. In dieser Studie konnte mittels eines Mausmodells in vivo gezeigt werden, dass die beiden Isoformen Dau c 1.01 und Dau c 1.02 des Hauptallergens aus Karotte, welche keine intakten IgE-Epitope mehr aufwiesen trotzdem noch in der Lage waren solche blockierenden Antikörper zu induzieren. Die Funktionalität dieser Antikörper mit IgE um das Allergen zu konkurrieren, wurde mittels Inhibition der Bindung von humanem IgE an das entsprechende Allergen durch Zugabe der entsprechenden Mausseren, welche die gebildeten IgG Antikörper enthielten, nachgewiesen und war vergleichbar mit der Inhibitionswirkung von Seren der Mäuse, die mit den Wildtyp-Allergenen immunisiert wurden. Wurden Proteine eingesetzt, die nicht nur eine zerstörte Struktur aufwiesen, sondern auch noch als Dimer der beiden Dau c 1 Isoformen mit zerstörter Struktur vorlagen (Dau c 1FP111P), so konnte eine verstärkte Induktion von blockierenden Antikörpern mit erhöhter IgE-Inhibitionswirkung beobachtet werden. Somit ist die Multimerisierung von Allergenen bei gleichzeitiger Zerstörung der Struktur ein geeigneter Ansatz zur Herstellung von hypoallergenen Proteinen.
Da Immuntherapeutika möglichst nicht in der Lage sein sollten allergische Reaktionen auszulösen, indem sie mit bestehenden IgE-Antikörpern kreuzreagieren, wurden die hier untersuchten hypoallergenen Proteine auch in Kreuzreaktivitätsstudien eingesetzt. Diese haben gezeigt, dass nur hohe Immunisierungsdosen zur Induktion von IgE führten, welches mit den Wildtyp-Allergenen kreuzreaktiv war. Da aber zur Induktion von blockierenden IgG-Antikörpern bereits eine geringe Dosis an verändertem Allergen ausreichend war, ist dies zu vernachlässigen.
Mittels Untersuchungen von IgE-bindenden-Epitopen und gezielter Veränderung von Allergenen, konnte in dieser Studie gezeigt werden, dass nicht nur die Zerstörung der Struktur oder die Oligomerisierung von Allergenen, sondern die Kombination der beiden Methoden eine geeignete Strategie zur Entwicklung neuer Reagenzien für die klassische spezifische Immuntherapie der Lebensmittelallergie darstellen kann.
The most frequently used parameters to describe the barrier properties of endothelial cells (ECs) in vitro are (i) the macromolecular permeability, indicating the flux of a macromolecular tracer across the endothelium, and (ii) electrical impedance of ECs grown on gold-film electrodes reporting on the cell layer's tightness for ion flow. Due to the experimental differences between these approaches, inconsistent observations have been described. Here, we present the first direct comparison of these assays applied to one single cell type (human microvascular ECs) under the same experimental conditions. The impact of different pharmacological tools (histamine, forskolin, Y-27632, blebbistatin, TRAP) on endothelial barrier function was analyzed by Transwell(®) tracer assays and two commercial impedance devices (xCELLigence(®), ECIS(®)). The two impedance techniques provided very similar results for all compounds, whereas macromolecular permeability readings were found to be partly inconsistent with impedance. Possible reasons for these discrepancies are discussed. We conclude that the complementary combination of both approaches is highly recommended to overcome the restrictions of each assay. Since the nature of the growth support may contribute to the observed differences, structure-function relationships should be based on cells that are consistently grown on either permeable or impermeable growth supports in all experiments.