TY  - THES
A1  - Glöckner, Herma
T1  - Characterization of a new miniaturized hollow-fiber bioreactor for cultivation of cell lines and primary cells to improve cytostatic drug testing in vitro
T1  - Charakterisierung eines neuartigen Hohlfaserbioreaktors zur Kultur von Zellinien und Primärzellen im Hinblick auf eine verbesserte Zytostatikatestung in vitro
N2  - Monolayer or suspension cell cultures are of only limited value as experimental models for human cancer. Therefore, more sophisticated, three-dimensional culture systems like spheroid cultures or histocultures are used, which more closely mimic the tumor in individual patients compared to monolayer or suspension cultures. As tissue culture or tissue engineering requires more sophisticated culture, specialized in vitro techniques may also improve experimental tumor models. In the present work, a new miniaturized hollow-fiber bioreactor system for mammalian cell culture in small volumes (up to 3 ml) is characterized with regard to transport characteristics and growth of leukemic cell lines (chapter 2). Cell and medium compartment are separated by dialysis membranes and oxygenation is accomplished using oxygenation membranes. Due to a transparent housing, cells can be observed by microscopy during culture. The leukemic cell lines CCRF-CEM, HL-60 and REH were cultivated up to densities of 3.5 x 107/ml without medium change or manipulation of the cells. Growth and viability of the cells in the bioreactor were the same or better, and the viable cell count was always higher compared to culture in Transwellâ plates. As shown using CCRF-CEM cells, growth in the bioreactor was strongly influenced and could be controlled by the medium flow rate. As a consequence, consumption of glucose and generation of lactate varied with the flow rate. Influx of low molecular weight substances in the cell compartment could be regulated by variation of the concentration in the medium compartment. Thus, time dependent concentration profiles (e.g. pharmacokinetic profiles of drugs) can be realized as illustrated using glucose as a model compound. Depending on the molecular size cut-off of the membranes used, added growth factors like GM-CSF and IL-3 as well as factors secreted from the cells are retained in the cell compartment for up to one week. Second, a method for monitoring cell proliferation the hollow-fiber bioreactor by use of the Alamar BlueTM dye was developed (chapter 3). Alamar BlueTM is a non-fluorescent compound which yields a fluorescent product after reduction e.g. by living cells. In contrast to the MTT-assay, the Alamar BlueTM-assay does not lead to cell death. However, when not removed from the cells, the Alamar BlueTM dye shows a reversible, time- and concentration-dependent growth inhibition as observed for leukemic cell lines. When applied in the medium compartment of a hollow-fiber bioreactor system, the dye is delivered to the cells across the hollow-fiber membrane, reduced by the cells and released from the cell into the medium compartment back again. Thus, fluorescence intensity can be measured in medium samples reflecting growth of the cells in the cell compartment. This procedure offers several advantages. First, exposure of the cells to the dye can be reduced compared to conventional culture in plates. Second, handling steps are minimized since no sample of the cells needs to be taken for readout. Moreover, for the exchange of medium, a centrifugation step can be avoided and the cells can be cultivated further. Third, the method allows to discriminate between cell densities of 105, 106 and 107 of proliferating HL-60 cells cultivated in the cell compartment of the bioreactor. Measurement of fluorescence in the medium compartment is more sensitive compared to glucose or lactate measurement for cell counts below 106 cells/ml, in particular. In conclusion, the Alamar BlueTM-assay combined with the hollow-fiber bioreactor offers distinct advantages for the non-invasive monitoring of cell viability and proliferation in a closed system. In chapter 4 the use of the hollow-fiber bioreactor as a tool for toxicity testing was investigated, as current models for toxicity as well as efficacy testing of drugs in vitro allow only limited conclusions with regard to the in vivo situation. Examples of the drawbacks of current test systems are the lack of realistic in vitro tumor models and difficulties to model drug pharmacokinetics. The bioreactor proved to be pyrogen free and is steam-sterilizable. Leukemic cell lines like HL-60 and primary cells such as PHA-stimulated lymphocytes can be grown up to high densities of 1-3 x 107 and analyzed during growth in the bioreactor by light-microscopy. The cytostatic drug Ara-C shows a dose-dependent growth inhibition of HL-60 cells and a dose-response curve similar to controls in culture plates. The bioreactor system is highly flexible since several systems can be run in parallel, soluble drugs can be delivered continuously via a perfusion membrane and gaseous compounds via an oxygenation membrane which also allows to control pO2 and pH (via pCO2) during culture in the cell compartment. The modular concept of the bioreactor system allows realization of a variety of different design properties, which may lead to an improved in vitro system for toxicity testing by more closely resembling the in vivo situation. Whereas several distinct advantages of the new system have been demonstrated, more work has to be done to promote in vitro systems in toxicity testing and drug development further and to reduce the need for animal tests.
N2  - Konventionelle Zellkulturmethoden, wie Monolayer- oder Suspensionskulturen weisen im Vergleich zu dreidimensionalen Kultursystemen (z.B. Sphäroid- oder Gewebekultur) wesentliche Limitationen auf. So sind in vitro Systeme als Modelle für humane Tumore häufig ungeeignet, besonders im Hinblick auf die Wirkstofftestung von Zytostatika. Dreidimensionale Kulturmodelle, die dem Verhalten von Tumoren in vivo besser entsprechen, erfordern technisch ausgereiftere Kulturtechniken als die konventionelle Zellkultur. Diese könnten dazu beitragen, eine dreidimensionale Kultur von Gewebe und dadurch in vivo ähnliche Bedingungen zu realisieren. In der vorliegenden Arbeit wurde ein neuentwickelter, miniaturisierter Hohlfaserbioreakor hinsichtlich seiner Transportcharakteristik, sowie bezüglich des Wachstums von leukämischen Zellinien untersucht (Kapitel 2). Der Zellkulturraum, mit einem Volumen von bis zu 3 ml, ist durch Dialysemembranen vom Mediumkompartiment getrennt. Eine zusätzliche Oxygenierung der Zellkultur erfolgt über Oxygenationsmembranen. Aufgrund der Verwendung eines transparenten Gehäuses können die Zellen während der Kultur mikroskopisch beobachtet werden. Die leukämischen Zellinien CCRF-CEM, HL-60 und REH konnten in dem neuen Hohlfaserbioreaktor in Zelldichten bis 3.5 x 107/ml kultiviert werden, ohne daß ein Mediumwechsel oder eine andere Manipulation der Zellkultur notwendig war. Das Wachstum und die Vitalität der Zellkulturen war vergleichbar oder besser als von Kontrollen in Transwellâ Kulturen. Wie für die Zellinie CCRF-CEM gezeigt werden konnte, war das Wachstum der Zellen abhängig von der Mediumflußrate und konnte durch deren Variation kontrolliert werden. Daraus resultierte auch ein veränderter Glukoseverbrauch und eine veränderte Laktatproduktion der Zellen. Der Eintrag von niedermolekularen Substanzen in den Zellkulturraum konnte durch die Variation der Konzentration der Substanz im Mediumkompartiment reguliert werden. Auf diese Weise können zeitabhängige Konzentrationsprofile, z. B. pharmakokinetische Profile von Wirkstoffen, realisiert werden, wie mit der Modellsubstanz Glukose gezeigt wurde. Abhängig vom molekularen Cut-off der verwendeten Membranen, werden im Zellkulturraum sowohl zugegebene, als auch autokrine Faktoren für bis zu einer Woche zurückgehalten, wie für GM-CSF oder IL-3 gezeigt wurde. Weiterhin wurde eine Methode entwickelt, um in dem miniaturisierten Hohlfaserbioreaktor die Zellproliferation mittels des Farbstoffes Alamar BlueTM zu ermitteln (Kapitel 3). Alamar BlueTM ist ein nicht-fluoreszierender Farbstoff, der nach Reduktion durch z.B. lebende Zellen in ein fluoreszierendes Produkt umgewandelt wird. Im Gegensatz zum MTT-Assay, führt der Alamar BlueTM-Assay jedoch nicht zum Zelltod. Wird der Farbstoff nicht aus der Zellkultur entfernt, zeigt sich eine reversible, zeit- und konzentrationsabhängige Wachstumsinhibiton der Zellen, wie für leukämische Zellinien gezeigt werden konnte. Verwendet man den Farbstoff im Mediumkompartiment eines Hohlfaserbioreaktor-System, wird er über die Hohlfasermembran zu den Zellen angeliefert, von den Zellen reduziert, und über die Membran wieder in das Mediumkompartiment abgeführt. Auf diese Weise reflektiert die Zunahme der Fluoreszenz im Mediumkompartiment das Wachstum der Zellen im Zellkulturraum. Das Verfahren bietet mehrere Vorteile: Erstens kann der Kontakt der Zellen mit dem Farbstoff im Vergleich zur konventionellen Zellkultur reduziert werden und das notwendige Handling wird minimiert, da keine Probennahme aus der Zellkultur zur Auswertung erforderlich ist. Zweitens ist zum Austauschen des Mediums kein Zentrifugationsschritt notwendig, so daß die Zellen ohne Störung weiterkultiviert werden können. Drittens erlaubt diese Methode eine Diskriminierung von Zelldichten von 105, 106 und 107 proliferierenden HL-60 Zellen im Zellkulturraum des Bioreaktors. Es konnte gezeigt werden, daß die Fluoreszenzmessung im Mediumkompartment im Vergleich zur Messung von Glukose oder Laktat besonders für Zellzahlen unterhalb 106 Zellen/ml sensitiver ist. Zusammenfassend bietet der Alamar BlueTM-Assay in Verbindung mit dem Hohlfaserbioreaktor klare Vorteile für ein nicht-invasives Monitoring der Zellvitalität und Proliferation in einem geschlossenen System. In Kapitel 4 wird die Verwendung des miniturisierten Hohlfaserbioreaktors als Modellsystem für toxikologische Untersuchungen beschrieben. Gegenwärtig fehlen realisitische in vitro Modelle, vor allem zur Modellierung von pharmakokinetischen Profilen. Der Bioreaktor erwies sich als pyrogenfrei und dampfsterilisierbar. Leukämische Zellinien, z. B. HL-60 Zellen sowie Primärzellen, wie z. B. PHA-stimulierte Lymphozyten konnten in Zelldichten bis zu 1-3 x 107 Zellen/ml kultiviert werden. Das Zytostatikum Ara-C wies eine dosisabhängige Wachstumsinhibition im Hohlfaserbioreaktor auf, wie für HL-60 Zellen gezeigt wurde. Die Dosis-Wirkungs-Kurve war vergleichbar dem Ergebnis in 96-Well-Platten. Das Bioreaktor System bietet eine hohe Flexibilität, da mehrere Systeme parallel untersucht werden können. Lösliche Substanzen können kontinuierlich über die Perfusionsmembran angeliefert werden und gasförmige Komponenten über die Oxygenationsmembran. Diese ermöglicht zudem eine Kontrolle des pO2 und des pH-Wertes (via pCO2) im Zellkompartiment während der Kultur. Das modulare Konzept des Bioreaktor Systems ermöglicht die Realisierung unterschiedlicher Designs. Obgleich einige deutliche Vorteile des neuen Bioreaktorsystems gezeigt wurden, müssen weitere Untersuchungen durchgeführt werden, um den Einsatz von in vitro Systemen in der Entwicklung neuer Wirkstoffe voranzutreiben und die Notwendigkeit von Tierexperimenten zu verringern.
KW  - Hohlfaserreaktor
KW  - Zellkultur
KW  - Cytostatikum
KW  - Hohlfaserbioreaktor
KW  - Zytostatikatestung
KW  - in vitro
KW  - hollow-fiber bioreactor
KW  - cytostatic drug testing
KW  - in vitro
Y1  - 2001
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-1181317
ER  - 
TY  - JOUR
A1  - Wäldchen, Sina
A1  - Lehmann, Julian
A1  - Klein, Teresa
A1  - van de Linde, Sebastian
A1  - Sauer, Markus
T1  - Light-induced cell damage in live-cell super-resolution microscopy
JF  - Scientific Reports
N2  - Super-resolution microscopy can unravel previously hidden details of cellular structures but requires high irradiation intensities to use the limited photon budget efficiently. Such high photon densities are likely to induce cellular damage in live-cell experiments. We applied single-molecule localization microscopy conditions and tested the influence of irradiation intensity, illumination-mode, wavelength, light-dose, temperature and fluorescence labeling on the survival probability of different cell lines 20-24 hours after irradiation. In addition, we measured the microtubule growth speed after irradiation. The photo-sensitivity is dramatically increased at lower irradiation wavelength. We observed fixation, plasma membrane permeabilization and cytoskeleton destruction upon irradiation with shorter wavelengths. While cells stand light intensities of similar to 1 kW cm\(^{-2}\) at 640 nm for several minutes, the maximum dose at 405 nm is only similar to 50 J cm\(^{-2}\), emphasizing red fluorophores for live-cell localization microscopy. We also present strategies to minimize phototoxic factors and maximize the cells ability to cope with higher irradiation intensities.
KW  - optical reconstruction microscopy
KW  - tag fusion proteins
KW  - localization microscopy
KW  - photodynamic therapy
KW  - diffraction limit
KW  - illumination microscopy
KW  - structured illumination
KW  - fluorescent probes
KW  - in vitro
KW  - dynamics
Y1  - 2015
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-145207
VL  - 5
IS  - 15348
ER  - 
TY  - JOUR
A1  - Tuchscherr, Lorena
A1  - Bischoff, Markus
A1  - Lattar, Santiago M.
A1  - Noto Llana, Mariangeles
A1  - Pförtner, Henrike
A1  - Niemann, Silke
A1  - Geraci, Jennifer
A1  - Van de Vyver, Hélène
A1  - Fraunholz, Martin J.
A1  - Cheung, Ambrose L.
A1  - Herrmann, Mathias
A1  - Völker, Uwe
A1  - Sordelli, Daniel O.
A1  - Peters, Georg
A1  - Loeffler, Bettina
T1  - Sigma factor SigB is crucial to mediate Staphylococcus aureus adaptation during chronic infections
JF  - PLoS Pathogens
N2  - Staphylococcus aureus is a major human pathogen that causes a range of infections from acute invasive to chronic and difficult-to-treat. Infection strategies associated with persisting S. aureus infections are bacterial host cell invasion and the bacterial ability to dynamically change phenotypes from the aggressive wild-type to small colony variants (SCVs), which are adapted for intracellular long-term persistence. The underlying mechanisms of the bacterial switching and adaptation mechanisms appear to be very dynamic, but are largely unknown. Here, we analyzed the role and the crosstalk of the global S. aureus regulators agr, sarA and SigB by generating single, double and triple mutants, and testing them with proteome analysis and in different in vitro and in vivo infection models. We were able to demonstrate that SigB is the crucial factor for adaptation in chronic infections. During acute infection, the bacteria require the simultaneous action of the agr and sarA loci to defend against invading immune cells by causing inflammation and cytotoxicity and to escape from phagosomes in their host cells that enable them to settle an infection at high bacterial density. To persist intracellularly the bacteria subsequently need to silence agr and sarA. Indeed agr and sarA deletion mutants expressed a much lower number of virulence factors and could persist at high numbers intracellularly. SigB plays a crucial function to promote bacterial intracellular persistence. In fact, \(\Delta\)sigB-mutants did not generate SCVs and were completely cleared by the host cells within a few days. In this study we identified SigB as an essential factor that enables the bacteria to switch from the highly aggressive phenotype that settles an acute infection to a silent SCV-phenotype that allows for long-term intracellular persistence. Consequently, the SigB-operon represents a possible target to develop preventive and therapeutic strategies against chronic and therapy-refractory infections.
KW  - gene regulator agr
KW  - endothelial cells
KW  - modulates virulence
KW  - death pathway sar locus
KW  - factor B
KW  - small-colony variants
KW  - alpha-toxin
KW  - epithelial cells
KW  - in vitro
Y1  - 2015
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-143419
VL  - 11
IS  - 4
ER  - 
TY  - JOUR
A1  - Dühring, Sybille
A1  - Germerodt, Sebastian
A1  - Skerka, Christine
A1  - Zipfel, Peter F.
A1  - Dandekar, Thomas
A1  - Schuster, Stefan
T1  - Host-pathogen interactions between the human innate immune system and Candida albicans - understanding and modeling defense and evasion strategies
JF  - Frontiers in Microbiology
N2  - The diploid, polymorphic yeast Candida albicans is one of the most important human pathogenic fungi. C. albicans can grow, proliferate and coexist as a commensal on or within the human host for a long time. However, alterations in the host environment can render C. albicans virulent. In this review, we describe the immunological cross-talk between C. albicans and the human innate immune system. We give an overview in form of pairs of human defense strategies including immunological mechanisms as well as general stressors such as nutrient limitation, pH, fever etc. and the corresponding fungal response and evasion mechanisms. Furthermore, Computational Systems Biology approaches to model and investigate these complex interactions are highlighted with a special focus on game-theoretical methods and agent-based models. An outlook on interesting questions to be tackled by Systems Biology regarding entangled defense and evasion mechanisms is given.
KW  - agent-based model
KW  - antimicrobial peptides
KW  - fungal pathogens
KW  - Candida albicans
KW  - immunological cross-talk
KW  - beta-lactamase inhibition
KW  - in vitro
KW  - biomaterial surfaces
KW  - biofilm formation
KW  - dendritic cells
KW  - infection
KW  - resistance
KW  - human immune system
KW  - host-pathogen interaction
KW  - computational systems biology
KW  - defense and evasion strategies
Y1  - 2015
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-151621
VL  - 6
IS  - 625
ER  - 
TY  - JOUR
A1  - Schilcher, Felix
A1  - Hilsmann, Lioba
A1  - Rauscher, Lisa
A1  - Değirmenci, Laura
A1  - Krischke, Markus
A1  - Krischke, Beate
A1  - Ankenbrand, Markus
A1  - Rutschmann, Benjamin
A1  - Mueller, Martin J.
A1  - Steffan-Dewenter, Ingolf
A1  - Scheiner, Ricarda
T1  - In vitro rearing changes social task performance and physiology in honeybees
JF  - Insects
N2  - In vitro rearing of honeybee larvae is an established method that enables exact control and monitoring of developmental factors and allows controlled application of pesticides or pathogens. However, only a few studies have investigated how the rearing method itself affects the behavior of the resulting adult honeybees. We raised honeybees in vitro according to a standardized protocol: marking the emerging honeybees individually and inserting them into established colonies. Subsequently, we investigated the behavioral performance of nurse bees and foragers and quantified the physiological factors underlying the social organization. Adult honeybees raised in vitro differed from naturally reared honeybees in their probability of performing social tasks. Further, in vitro-reared bees foraged for a shorter duration in their life and performed fewer foraging trips. Nursing behavior appeared to be unaffected by rearing condition. Weight was also unaffected by rearing condition. Interestingly, juvenile hormone titers, which normally increase strongly around the time when a honeybee becomes a forager, were significantly lower in three- and four-week-old in vitro bees. The effects of the rearing environment on individual sucrose responsiveness and lipid levels were rather minor. These data suggest that larval rearing conditions can affect the task performance and physiology of adult bees despite equal weight, pointing to an important role of the colony environment for these factors. Our observations of behavior and metabolic pathways offer important novel insight into how the rearing environment affects adult honeybees.
KW  - honeybee
KW  - artificial rearing
KW  - behavior
KW  - in vitro
KW  - juvenile hormone
KW  - triglycerides
KW  - PER
KW  - foraging
KW  - nursing
Y1  - 2021
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-252305
SN  - 2075-4450
VL  - 13
IS  - 1
ER  - 
TY  - JOUR
A1  - Heydarian, Motaharehsadat
A1  - Rühl, Eva
A1  - Rawal, Ravisha
A1  - Kozjak-Pavlovic, Vera
T1  - Tissue models for Neisseria gonorrhoeae research — from 2D to 3D
JF  - Frontiers in Cellular and Infection Microbiology
N2  - Neisseria gonorrhoeae is a human-specific pathogen that causes gonorrhea, the second most common sexually transmitted infection worldwide. Disease progression, drug discovery, and basic host-pathogen interactions are studied using different approaches, which rely on models ranging from 2D cell culture to complex 3D tissues and animals. In this review, we discuss the models used in N. gonorrhoeae research. We address both in vivo (animal) and in vitro cell culture models, discussing the pros and cons of each and outlining the recent advancements in the field of three-dimensional tissue models. From simple 2D monoculture to complex advanced 3D tissue models, we provide an overview of the relevant methodology and its application. Finally, we discuss future directions in the exciting field of 3D tissue models and how they can be applied for studying the interaction of N. gonorrhoeae with host cells under conditions closely resembling those found at the native sites of infection.
KW  - ex vivo
KW  - biomimetic tissue models
KW  - Neisseria gonorrhoeae
KW  - in vivo
KW  - in vitro
Y1  - 2022
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-263046
SN  - 2235-2988
VL  - 12
ER  -