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Impact of pectin dietary supplementation on experimental food allergy via gut microbiota modulation
(2023)
In recent years, dietary fibers gained focus in regard of their immune-modulatory effects and the potentially beneficial effect on allergies. The dietary fiber and prebiotic pectin is able to promote growth and activity of beneficial bacteria and thereby induce modulation of different immune responses. However, structurally different types of pectin might promote different immune-modulatory responses and to date the optimal pectin type for induction of beneficial health effects is not identified. Furthermore, it is still unclear, whether pectins provide a beneficial effect on certain allergies, such as food allergy.
Having this in consideration, this study examined the immune-modulatory effects of structurally different pectins on naive as well as peach allergic mice. Furhtermore, the impact of dietary pectin supplementation on composition and diversity of the murine gut microbiota was determined.
This study showed that dietary pectin intervention was able to suppress allergy-related Th2 responses considering humoral and cellular immune responses. Only apple-derived high-methoxyl pectin revealed an impact on total IgA levels and affected the microbial richness. Furthermore, it is not known whether the effects observed with the two pectins are caused by modulations of the bacterial composition or induced at least partly by direct interaction with the immune cells. Further studies are required to fully understand the mechanisms underlying the immune-modulatory capacities of different pectins.
Finally, the obtained results generated evidence that dietary pectin intervention can beneficially modulate the immune response in healthy mice and – at least partially – suppress allergy-related immune responses in a model of food allergy, depending on the structural characteristics of the used pectin.
Mitochondria perform essential energetic, metabolic and signalling functions within the cell. To fulfil these, the integrity of the mitochondrial proteome has to be preserved. Therefore, each mitochondrial subcompartment harbours its own system for protein quality control. However, if the capacity of mitochondrial chaperones and proteases is overloaded, mitochondrial misfolding stress (MMS) occurs. Upon this stress condition, mitochondria communicate with the nucleus to increase the transcription of nuclear encoded mitochondrial chaperones and proteases. This proteotoxic stress pathway was termed the mitochondrial unfolded protein response (UPRmt) aiming at restoring protein homeostasis. Despite being discovered over 25 years ago, the signalling molecules released by stressed mitochondria as well as the corresponding receptor and transcription factor remain poorly understood. With this study, we aimed at characterising the underlying signalling events and mechanisms of how mitochondria react to misfolded proteins. First, we aimed to establish different methods to induce MMS that triggers the transcriptional induction of mitochondrial chaperones and proteases detected by quantitative polymerase chain reaction. We were able to induce UPRmt signalling by overexpression of an aggregation-prone protein and by knock-down or inhibition of mitochondrial protein quality control components. To study the signalling in a time-resolved manner, we focused on the usage of the mitochondrial HSP90 inhibitor GTPP and the mitochondrial LONP1 protease inhibitor CDDO.
Early time point RNA sequencing analysis of cells stressed with GTPP or CDDO revealed upregulated genes in response to oxidative stress. Indeed, measurements of mitochondrial superoxide with the fluorescent dye MitoSOX showed increased levels of reactive oxygen species (ROS) upon MMS induction. In contrast, there was no induction of mitochondrial chaperones and proteases when combining MMS with antioxidants. Compartment-specific targeting of the hydrogen peroxide sensor HyPer7 revealed increased ROS levels in the intermembrane space and matrix of mitochondria, followed by elevated ROS levels in the cytosol at later time points. The importance of cytosolic ROS for the signalling was supported by preventing UPRmt induction with an inhibitor blocking the outer mitochondrial membrane pore. Thus, ROS were identified as an essential UPRmt signal.
To understand which cytosolic factor is modified by ROS, redox proteomics was performed. Here, reversible changes on cysteine residues of the HSP40 co-chaperone DNAJA1 were observed upon MMS. Consequently, transcriptional induction of UPRmt genes was abolished by DNAJA1 knock-down. To understand the function of DNAJA1 during UPRmt signalling, quantitative interaction proteomics upon MMS revealed an increased binding to mitochondrial proteins and its interaction partner HSP70. Immunoprecipitation confirmed a ROS-dependent interaction between HSP40 and HSP70. Increased binding to mitochondrial proteins represented a cytosolic interaction of DNAJA1 with mitochondrial precursor proteins, whose accumulation was confirmed by western blot. Moreover, a fluorescent protein targeted to mitochondria accumulated in the cytosol during GTPP treatment, confirming a reduced import efficiency upon MMS. Preventing the accumulation of precursors by a translation inhibitor or depletion of a general mitochondrial transcription factor resulted in reduced UPRmt activation. Thus, DNAJA1 is essential for UPRmt signalling, since its oxidation by mitochondrial ROS and its enhanced recruitment to mitochondrial precursors allows the integration of both MMS-induced signals.
To link these findings to an increased transcription of mitochondrial chaperones and proteases, we screened for transcription factors accumulating in the nucleus upon MMS by cellular fractionation mass spectrometry. We demonstrated that specifically HSF1 accumulates in nuclei of cells stressed with GTPP or CDDO. Depletion of HSF1 by knock-down or knock-out resulted in the abrogation of the UPRmt-specific transcriptional response. HSF1 activation was visualised by nuclear accumulation on western blot, a process inhibited by ROS and precursor suppression. Moreover, DNAJA1 depletion prevented HSF1 activation. Ultimately, we proved by immunoprecipitation that the inhibitory interaction between HSF1 and HSP70 is reduced upon MMS.
Thus, we conclude that MMS increases mitochondrial ROS that are released into the cytosol. In addition, the import efficiency is reduced upon MMS, resulting in the accumulation of non-imported mitochondrial precursor proteins in the cytosol. Both signals are recognised via DNAJA1 oxidation and substrate binding. The concurrent recruitment of HSP70 to DNAJA1 results in the loss of the inhibitory HSP70-HSF1 interaction. Thus, active HSF1 can migrate to the nucleus to initiate transcription of mitochondrial chaperones and proteases. These findings are in accordance with observations in yeast, where mistargeted mitochondrial proteins activate cellular stress responses. Our results highlight a surprising interconnection and dependence of the mitochondrial and the cytosolic proteostasis network, in which the UPRmt is activated by a combination of two mitochondria-specific proteotoxic stress signals.
Bioactive small molecules are used in many research areas as important tools to uncover biological pathways, interpret phenotypic changes, deconvolute protein functions and explore new therapeutic strategies in disease relevant cellular model systems. To unlock the full potential of these small molecules and to ensure reliability of results obtained in cellular assays, it is crucial to understand the properties of these small molecules. These properties encompass their activity and potency on their designated target(s), their selectivity towards unintended off-targets and their phenotypic effects in a cellular system. Approved drugs often engage with multiple targets, which can be beneficial for some applications such as treatment of cancer where several pathways need to be inhibited for treatment efficacy. However, targeting multiple key proteins in diverse pathways also increases the possibility for unspecific or unwanted side effects. For many drugs the entire target space that they modulate is not known. This makes it difficult to use these drugs for target deconvolution or functional assays with the aim to understand the underlying biological processes. In contrast to drugs, for mechanistic studies, a good alternative are chemical tool compounds so called chemical probes that are usually exclusively selective as well as chemogenomic compounds, that inhibit several targets but have narrow selectivity profiles. Because they are mechanistic tools, chemical tool compounds must meet stringent quality criteria and they are therefore well characterized in terms of their potency, selectivity and cellular on-target activity. To ensure that an observed phenotypic effect caused by a compound can be attributed to the described target(s), it is essential to study also properties of chemical tools leading to unspecific cellular effects. There are a variety of unspecific effects that can be caused by physiochemical compound properties that can interfere with phenotypic assays as well as functional compound evaluations. One of these effects is low solubility causing toxicity or intrinsic fluorescence potentially interfering with assay readouts. But unanticipated cellular responses can also arise from unspecific binding, accumulation in cellular compartments or damage caused to organelles such as mitochondria or the cytoskeleton that can result in the induction of diverse forms of cell death.
In this study, we investigated the influence of a variety of small molecules on distinct cell states, by establishing and validating high-content imaging assays, which we called Multiplex assay. This assay portfolio enabled us to detect different cellular responses using diverse fluorescent reporters, such as the influence of a compound on cell viability, induction of cell death programs and modulation of the cell cycle. Additionally, general compound properties such as precipitation and intrinsic fluorescence were simultaneously detected. The assay is adaptable to assess other cellular properties of interest, such as mitochondrial health, changes in cytoskeletal morphology or phospholipidosis. A significant advantage of the assay is that we are using live cells, so we can capture dynamic cellular changes and fluctuations that can be crucial for the understanding of cellular responses.
Der Hirntumor Glioblastom (GBM) ist aufgrund seines infiltrativen Wachstums, der hohen intra- und intertumoralen Heterogenität, der hohen Therapieresistenz als auch aufgrund der sogenannten gliomartigen Stammzellen sehr schwer zu behandeln und führt fast immer zu Rezidiven. Da es in den letzten Jahrzehnten kaum Fortschritte in der Behandlung des GBMs gab, bis auf die Therapie mit Tumortherapiefeldern, wird weiterhin nach alternativen Zelltodtherapien geforscht, wie zum Beispiel dem Autophagie-abhängigen Zelltod. Der Autophagie-abhängige Zelltod ist durch einen erhöhten autophagischen Flux gekennzeichnet und obwohl die Autophagie, als auch selektive Formen wie die Lysophagie und Mitophagie, normalerweise als überlebensfördernde Mechanismen gelten, konnten viele Studien eine duale Rolle in der Tumorentstehung, -progression und -behandlung aufzeigen, die vor allem vom Tumortyp und stadium abhängt. Um die zugrunde liegenden Mechanismen des durch Medikamente induzierten Autophagie-abhängigen Zelltods im GBM weiter zu entschlüsseln, habe ich in meiner Dissertation verschiedene Substanzen untersucht, die einen Autophagie-abhängigen Zelltod induzieren.
In einer zuvor in unserem Labor durchgeführten Studie konnte gezeigt werden, dass das Antipsychotikum Pimozid (PIMO) und der Opioidrezeptor-Antagonist Loperamid (LOP) einen Autophagie-abhängigen Zelltod in GBM Zellen induzieren können. Darauf aufbauend habe ich die Fähigkeit zur Induktion des Autophagie-abhängigen Zelltods in weiteren Zellmodellen validiert. Dies bestätigte einen erhöhten autophagischen Flux nach PIMO und LOP Behandlung, während der Zelltod als auch der autophagische Flux in Autophagie-defizienten Zellen reduziert war. In weiteren Versuchen konnte ich die Involvierung der LC3-assoziierten Phagozytose (LAP), ein Signalweg der auf die Funktion einiger autophagischer Proteine angewiesen ist, ausschließen. Weiterhin konnte ich eine massive Störung des Cholesterin- und Lipidstoffwechsels beobachten. Unter anderem akkumulierte Cholesterin in den Lysosomen gefolgt von massiven Schäden des lysosomalen Kompartiments und der Permeabiliserung der lysosomalen Membran. Dies trug einerseits zur Aktivierung überlebensfördernder Lysophagie als auch der Zell-schädigenden „Bulk“-Autophagie bei. Letztendlich konnte aber die erhöhte Lysophagie die Zellen nicht vor dem Zelltod retten und die Zellen starben einen Autophagie-abhängigen lysosomalen Zelltod. Da die Eignung von LOP als Therapie für das GBM aufgrund der fehlenden Blut-Hirn-Schranken Permeabilität und von dem Antipsychotikum PIMO aufgrund teils schwerer Nebenwirkungen eingeschränkt ist, habe ich mich im weiteren Verlauf meiner Dissertation mit einer Substanz mit einem anderen Wirkmechanismus beschäftigt.
Der Eisenchelator und oxidative Phosphorylierungs (OXPHOS) Inhibitor VLX600 wurde zuvor berichtet mitochondriale Dysfunktion und Zelltod in Kolonkarzinomzellen zu induzieren. Allerdings hat meines Wissens nach bisher noch keine Studie die therapeutische Eignung von VLX600 für das GBM untersucht. Hier zeige ich eine neuartige Autophagie-abhängige Zelltod-induzierende Fähigkeit von VLX600 für GBM Zellen, da der Zelltod signifikant in Autophagie-defizienten Zellen aber nicht durch Caspase-Inhibitoren gehemmt wurde und der autophagische Flux erhöht war. Darüber hinaus konnte ich die Hemmung der OXPHOS und die Induktion von mitochondrialem Stress in GBM Zellen bestätigen und weiterhin aufzeigen, dass VLX600 nicht nur die mitochondriale Homöostase stört, sondern auch zu einer BNIP3-BNIP3L-abhängigen Mitophagie führt, die wahrscheinlich durch HIF1A reguliert wird aber keinen erkennbaren Nettoeffekt auf den von VLX600 induzierten Zelltod hat. Demnach induziert VLX600 letale „Bulk“-Autophagie in den hier verwendeten Zellmodellen. Darüber hinaus konnte ich zeigen, dass die Eisenchelatierung durch VLX600 eine große Rolle für den von VLX600-induzierten Zelltod spielt aber auch für die Mitophagie Induktion, Histon Lysin Methylierung und den ribosomalen Stress. Letztendlich ist es wahrscheinlich ein Zusammenspiel all dieser Faktoren, die zur Zelltodinduktion durch VLX600 führen und interessanterweise werden Eisenchelatoren bereits in präklinischen und klinischen Studien für Krebstherapien untersucht. Dabei könnten gewisse metabolische Eigenschaften verschiedener Tumorzellen die Sensitivität von Wirkstoffen, die auf den Metabolismus wirken wie VLX600, beeinflussen was in zukünftigen Studien beachtet werden sollte um den bestmöglichsten Therapieerfolg zu erzielen. Zusammenfassend unterstützt meine Dissertation die duale Rolle der Autophagie, die stark vom jeweiligen Kontext abhängt und befürwortet die weitere Forschung von Substanzen, die einen Autophagie-abhängigen Zelltod induzieren, für das GBM.
The transcriptional regulator RcsB controls the expression of a minimum of 20 different genes having diverse functionalities and biosynthetic operons in the family of Enterobacteriaceae. While in the heterodimeric complex with the co activator RcsA, the RcsAB box consensus is recognized, DNA binding sites for RcsB without RcsA have also been identified. The conformation of RcsB might therefore be modulated upon interaction with various co activators, resulting in recognition of different DNA targets. In this study the interaction of RcsB with some of these DNA targets have been analysed by a diverse array of techniques including gel shift assay and SPR. The solution structure of the C-terminal DNA-binding domain of RcsB from Erwinia amylovora spanning amino acid residues 129-215 has been solved in this study by heteronuclear NMR spectroscopy. The C-terminal domain is composed of four α-helices where the two central helices of the H-T-H motif are similar to the structures of the regulatory proteins GerE, NarL and TraR. The DNA-binding activity of the C-terminal domain alone is established for the first time in this study and was specified by fluorescence spectroscopy, SPR and NMR titration experiments. The molecular interaction between the individual RcsB domains was analysed by cross-linking experiments and heteronuclear NMR spectroscopy and the amino acid residues of the C-terminal domain involved in this interaction were identified precisely. Another important part of this project was the cell-free production of different Trp analogue labelled RcsB protein. RcsB protein was produced in quite a good yield with different Trp analogue having spectrally enhanced properties. The isolated RcsB alloproteins proved to be ideal for protein interaction studies by fluorescence spectroscopy and the very first evidence of an oligomerization of RcsB due to molecular association has been put forth from these studies. The phosphorylated state of the RcsB protein was mimicked by a beryllofluoride complex in order to study its role in transcriptional regulation. It was found that RcsB alone could bind to DNA targets upon this modification by the beryllofluoride complex. Thus the phosphorylation of the protein that involves the Asp 56 residue induces a structural change of the protein followed probably by a domain movement also, so that the C-terminal domain having the H-T-H DNA binding motif that was previously eclipsed by the N-terminal domain is relieved of this constraint.
Nitric oxide (NO) is a potent mediator with pleiotropic functions such as inhibition of platelet aggregation, smooth muscle relaxation and regulation of neuronal transmission. These effects are mostly mediated by intracellular NO-sensitive guanylyl cyclases (GCs) which convert GTP into the second messenger, cGMP. This messenger in turn activates multiple downstream effectors such as cGMP-dependent protein kinases, cGMP-regulated ion channels and cGMPdependent phosphodiesterases. Mammalian NO-sensitive GCs are obligate heterodimers of an α and β subunit each. Given that these enzymes play a key role in cGMP-mediated pathways, one may anticipate that mechanisms other than allosteric activation via NO may exist to regulate the production and turnover of cGMP. In this thesis, novel aspects of the regulation of the most abundantly expressed GC heterodimer α1β1 are presented.
A possible mechanism of regulation that was tested here, is tyrosine phosphorylation. Using anti-phosphotyrosine antibodies, the phosphorylation of the β1 subunit was detected after incubation of β1-overexpressing COS-1 cells with protein tyrosine phosphatase (PTP) inhibitors such as pervanadate and bpV(phen). β1 phosphorylation on tyrosines was also observed in PC-12 cells which endogenously express GC and in rat aorta after inhibition of PTPs. Furthermore, hydrogen peroxide was found to be a physiological stimulus for the induction of reversible β1 tyrosine phosphorylation in intact cells. Using phenylalanine mutants of different tyrosines, residue 192 (Y192) of β1 was identified as the major phosphorylation site. Consistent with this finding, sequence analyses showed that Y192 forms part of a motif that resembles a preferential target site for Src-like kinases. When tyrosine-phosphorylated, this motif exposes a typical SH2 docking site for members of the Src kinase family.
Experiments with inhibitors of Src kinases, PP1 and PP2, clearly showed that phosphorylation of Y192 is Src-dependent. Preincubation of β1-expressing cells with these inhibitors significantly reduced the level of phosphorylated β1 after bpV(phen) treatment. Furthermore, co-expression of β1 with Src led to a strong phosphorylation of this subunit. Co-precipitation experiments showed that Src interacts with GC. Interestingly, kinases of the Src family are recruited to β1 via the SH2 domain upon phosphorylation of Y192. Together, these results indicate that Src kinases phosphorylate tyrosine 192 thereby creating a docking site for their own SH2 domains. Kinase bound to GC may then catalyze phosphorylation of GC or other downstream effectors. Inhibition of PTPs altered GC activity in two ways: it increased both the basal activity and the YC-1- and BAY 41-2272-stimulated activity two-fold, and it reduced the sensitivity of the enzyme towards NO. The detailed mechanism of action is still unknown, but experiments using the mutant β1[Y192F] demonstrated that residue 192 is not responsible for these effects.
Another major focus of this thesis was the identification of novel GC binding proteins. Using the yeast two-hybrid approach, the carboxy-terminal portion of a protein named AGAP1 (amino acid (aa) 399-804) was found to interact with the catalytic domain of α1 (aa 466-690) and with the regulatory domain of β1 (aa 1-348). Human AGAP1 is a multidomain protein of 804 amino acids with a calculated molecular mass of 89,1 kDa comprising an Arf-GAP (GAP:GTPase activating protein), a putative GTPase domain, two Ankyrin repeats and a PHdomain. Co-precipitation experiments using lysates from mammalian cells overexpressing both binding partners confirmed the interaction of AGAP1 with the GC subunits. Immunofluorescence analyses demonstrated that AGAP1 co-localizes with GC in the cytoplasm of COS-1 cells.
In Northern blots, AGAP1 mRNA was detected in various human and murine tissues showing a comparable expression pattern described for the mRNA of α1 and β1. Using an AGAP1-specific antibody, endogenous protein was precipitated from lysates of HEK-293 cells derived from human embryonic kidney. The same antibody efficiently cross-reacted with the rat homologue (rAGAP1) and immunoprecipitated endogenous rAGAP1 from lysates of PC-12 cells, aorta and heart. The molecular mass of rAGAP1 is larger than that of the human protein, possibly due to an additional exon present in the rat genome. Like β1, AGAP1 is a substrate for tyrosine kinases. Phosphorylation of AGAP1 was detected after inhibition of PTPs or by coexpression of Src. Furthermore, the kinase inhibitor PP2 strongly impaired phosphorylation of AGAP1 after pervanadate treatment suggesting that tyrosine kinases of the Src family are involved. Measurements of cGMP production showed that AGAP1 has no influence on the activity of NO-sensitive GC. Interestingly, inhibition of PTPs potently increased the complex formation between AGAP1 and GC indicating that the interaction between these two proteins is modulated by reversible tyrosine phosphorylation. Whether this effect is due to the phosphorylation of AGAP1 or GC is still unknown. AGAP1 associates with endosomes and exposes Arf-GAP activity towards Arf1 and Arf5 which are involved in vesicular transport. Thus, one may hypothesize that binding of α1β1 to AGAP1 targets GC to distinct subcellular compartments in close proximity to cGMP-dependent effectors, thereby optimizing cGMP generation and fostering cGMP-driven actions.
Taken together, these results demonstrate that beside the modulation of GC by NO the enzyme is regulated by tyrosine phosphorylation and interaction with AGAP1.
Aim of the present study was the characterization of the RORa receptor (Retinoidrelated Orphan Receptor a). RORa is a member of the nuclear receptor family and is involved into the differentiation of Purkinje cells, inflammation, arteriosclerosis, and bone mineralization. Nuclear receptors are transcription factors and mediate biological responses within target cells to outer signals such as lipophilic hormones. They are involved in development, growth, differentiation, proliferation, apoptosis, and maintenance of homeostasis. Ligand binding, posttranslational modifications, and cofactor recruitment control their activity. Nearly all nuclear receptors share a common modular structure with an Nterminal A/B region, a DNA-binding domain (DBD) that is composed of two zinc finger motifs, a hinge region, and a C-terminal ligand-binding domain (LBD). The RORs comprise the subtypes RORa, RORb, and RORg, which are encoded by different genes. All isoforms of the respective subtypes only differ in their A/B domain. This study focused mainly on the exploration of the gene structure, expression, and subcellular distribution of RORa...
Metastatic rhabdomyosarcoma (RMS) is one of the most challenging tumor entities in pediatric oncology caused by treatment resistances and immune escape. Novel chimeric antigen receptor (CAR) immunotherapies as specific, effective and safe treatment provide antitumor cytotoxicity by soluble factors and ligands/receptor signals. Besides its intrinsic potential as innate immune cell the ErbB2-sprecific CAR-engineered natural killer (NK)-92 cell line NK-92/5.28.z also provides CAR-mediated cytotoxicity, resulting in a high lytic capacity against 2D and 3D RMS cell structures in vitro. Also in a xenograft model using immune deficient NOD/Scid/IL2Rγ-/- (NSG) mice inhibited NK-92/5.28.z the tumor growth as long as the cells were administered and therefore prolonged the survival of the animals. The NK-92/5.28.z were distributed by the blood circulation and subsequently infiltrated the tumor tissue. Due to the malignant origin of the NK-92 cell line the cells must be irradiated prior to the use in patients. While the irradiation hampered the proliferation of NK-92/5.28.z cells, the cytotoxicity against RMS cells in vitro is retained for at least 24 hours. In the xenograft model irradiated NK-92/5.28.z cells inhibited the tumor growth but to a lower extent than untreated cells, as irradiated cells have only a limited life span in vivo no durable persistence and remission was achieved. Therefore, combinatorial approaches were focused and while blocking of the PD-1/PD-L1 axis did not resulted in a significantly enhanced tumor cell lysis, the combinatorial treatment with proteasome inhibitor bortezomib exhibited a significant enhanced cytotoxicity against RMS cells at least in vitro. Bortezomib itself induces caspase mediated apoptosis and also the upregulates the expression of TRAIL receptor DR5. The corresponding ligand TRAIL is expressed on the surface of the NK-92/5.28.z and pursuing experiments with purified TRAIL and bortezomib revealed a synergism. NK-92/5.28.z as an off-the-shelf product is therefore feasible for the therapy of metastatic RMS, but it might be necessary to support the cytotoxicity by additive agents like proteasome inhibitor bortezomib to archive durable remission.
Another cell population suitable for RMS CAR-immunotherapy are cytokine induced killer (CIK) cells, a heterogenous cell population generated from autologous PBMCs consisting of T, NK and T-NK cells. Lentivirally transduced ErbB2-specific CAR-CIK cells were previously shown to inhibit the tumor engraftment in a RMS xenograft model. However, lentiviral transduced adoptive immunotherapies bear risks for the transfer in patients, therefore the Sleeping Beauty Transposon System (SBTS) as a non-viral method, which integrates the CAR coding DNA by a cut-and-paste mechanism from a minicircle (MC) into the CIK cells genome is more feasible for the generation of CAR-CIK cells. The Sleeping beauty transposase mRNA and the MC were transferred in the cell by nucleofection, different factors influence the transfection efficiency and viability of the CIK cells in this harsh procedure. In preliminary experiments with MC Venus, a MC encoding eGFP, the highest transfection efficiency with the best proliferative capacity was achieved with cells on day 3 of CIK culture and without the addition of autologous monocytes as feeder cells. For the CAR construct the protocol was further improved by adjusting crucial factors, for this construct the best results were achieved on day 0, without irradiated PBMCs as feeder cells and cultivation in X-Vivo10 medium supplemented with human fresh frozen plasma. The X-Vivo10 medium enhanced the percentage of NK- and T-NK cells significantly compared to CAR-CIK cells cultured in RPMI. Since the gene transfer by SBTS resulted in CAR-CIK cells stably expressing a CAR in all subpopulations, resulting in a significantly enhanced cytotoxicity against RMS cells in vitro, these cells were compared to lentiviral transduced CAR-CIK cells in vitro and in vivo. While the SBTS CAR-CIK cells were superior to viral CAR-CIK cells in 2D short-term assays, the viral cells showed higher lytic capacity in 3D spheroid long-term assays. In a RMS xenograft model lentiviral CAR-CIK cells significantly prolonged the survival of mice and persisted, whereas SBTS CAR-CIKs did not favor the overall survival compared to untreated controls and also did not persist. Phenotypic analysis revealed a highly cytotoxic CD8+ and late effector memory dominant phenotype for SBTS CAR-CIK cells supporting short-term cytotoxicity but also more prone for exhaustion, while viral CAR-CIK cells showed a more balanced phenotype for memory and cytotoxicity. Therefore, the SBTS is feasible for the ErbB2-CAR gene transfer in CAR-CIK resulting in a stable CAR-expression with high short-term cytotoxicity, but these cells are also more prone to exhaustion and the protocol might be adapted further to prevent this limitation for in vivo application.
This work underlines the hard-to-treat characteristics of metastatic RMS, but also shows some approaches for further evaluation like the combination of NK-92/5.28.z cells with bortezomib and the feasibility of the generation of CAR-CIK cells via SBTS.
Die Zahl der gramnegativen Bakterien auf der WHO-Liste der Antibiotikaresistenzen hat in den letzten Jahrzehnten erheblich zugenommen. Schätzungen zufolge wird die Antibiotikaresistenz bis 2050 tödlicher sein als Krebs. Die äußere Membran gramnegativer Bakterien ist aufgrund ihres wichtigsten Strukturbestandteils, des Lipopolysaccharids (LPS), sehr anpassungsfähig an Umweltveränderungen. Das LPS macht gramnegative Bakterien von Natur aus resistent gegen viele Antibiotika und führt somit zu Antibiotikaresistenz. Der bakterielle ATP-bindende Kassettentransporter (ABC-Transporter) MsbA spielt eine entscheidende Rolle bei der Regulierung der bakteriellen Außenmembran, indem er das Kern-LPS durch ATP-Hydrolyse über die Innenmembran von gramnegativen Bakterien flockt. Darüber hinaus fungiert diese Floppase als Efflux-Pumpe, indem sie Medikamente durch die innere Membran transportiert, was sie zu einem interessanten Ziel für Medikamente macht. Vor kurzem wurden zwei verschiedene Klassen von MsbA-Inhibitoren entdeckt: (1) Tetrahydrobenzothiophene (TBT), die den LPS-Transport aufheben, und (2) Chinolinderivate, die sowohl die ATP-Hydrolyse als auch die LPS-Translokation blockieren. Darüber hinaus hat die Bestimmung der 3D-Struktur von MsbA durch Rontgen- und Kryo-EM mehrere interessante Zustände der Floppase ergeben. Die Kernspinresonanzspektroskopie ist eine hervorragende biophysikalische Methode zur Ergänzung der vorhandenen 3D-Strukturdaten. Insbesondere ermöglicht die Festkörper-NMR die Untersuchung von Membranproteinen in einer nativen Umgebung (z. B. in einer Lipiddoppelschicht). In der Vergangenheit hat unser Labor mithilfe der Festkörper-NMR einige detaillierte Mechanismen von MsbA aufgedeckt. Trotz der zahlreichen Fortschritte bei der Untersuchung der ABC-Transporterprotein-Superfamilie ist der spezifische Prozess der Substrattranslokation von MsbA noch immer unbekannt. Es wird angenommen, dass dieser Translokationsprozess über die Kopplungshelices (CHs) erfolgt, die sich zwischen der Transmembranregion (TMD) und der Nukleotidbindungsdomäne (NBD) befinden. Nukleotid-Bindungsdomäne (NBD). Zu diesem Zweck wird dem Zusammenspiel zwischen der TMD und der NBD über die CHs besondere Aufmerksamkeit gewidmet, mit dem Ziel, den Prozess der Substrattranslokation mithilfe von funktionellen Assays und Festkörper-NMR zu verstehen. Bei letzterem wurden spezifische Reporter in die CHs eingeführt, um Konformationsänderungen in 2D-spektroskopischen Daten zu verfolgen. Darüber hinaus wurde zeitaufgelöste NMR eingesetzt, um die Auswirkungen verschiedener Substrate in der TMD während der ATP-Hydrolyse in der NBD sichtbar zu machen. Die einzigartigen Reporter in den CHs haben Konformationsänderungen in bestimmten katalytischen Zuständen gezeigt. Darüber hinaus scheinen verschiedene Substrate die Kinetik der ATP-Hydrolyse zu beeinflussen. Die Ergebnisse zeigten, dass einige Substrate einen bevorzugten katalytischen Zustand innerhalb des ATP-Hydrolyse Zyklus aufweisen, der möglicherweise einen gekoppelten oder ungekoppelten Kinasemechanismus hat. Diese Ergebnisse könnten verschiedene Einblicke in die molekulare Struktur potenzieller neuer Antibiotika liefern.