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Oral administration of drugs is the most common, convenient, safest and economical route of drug administration. There is lack of established tools to study the function of transporters in the intestinal absorption of drugs. Because of its favorable physico-chemical, pharmacokinetic and pharmacodynamic characteristics, trospium could be potentially used as a probe substrate to study the function of drug transporters. Therefore, this study was conducted to examine the suitability of trospium chloride as a probe drug to study the function of multidrug transporters in the human body. To this end, two randomized, controlled, four-period, cross-over pharmacokinetic drug interaction studies of oral and intravenous trospium with co-medication of oral clarithromycin or ranitidine were performed in 24 healthy subjects to mechanistically characterize the role of P-gp, OATP1A2, OCT1, OCT2, MATE1 and MATE2-K in the absorption and disposition of trospium. The contribution of the drug transporters in the absorption and disposition of trospium were examined in isolated systems using in vitro uptake and inhibition assays in transporter transfected human cell lines.
OCT1 (Vmax = 0.8 ± 0.1 nmol/min × mg) is a high capacity transporter of trospium compared to OCT2 (Vmax = 0.04 ± 0.01 nmol/min × mg). But the OCT2 (Km = 0.5 ± 0.1 µM) transporter demonstrated a high affinity in the transport of trospium compared to OCT1 (Km = 17.4 ± 2.1 µM). OCT1 genetic alleles *2, *3, *4 and *7 resulted in significant loss of activity and the alleles *5 and *6 caused complete loss of uptake of trospium. The common OCT2 genetic allele Ser270 caused slight but significant increase in activity of OCT2.
Ranitidine inhibits OCT1 (IC50 = 186 ± 25 µM), MATE1 (IC50 = 134 ± 37 µM) and MATE2-K (IC50 = 35 ± 11 µM)-mediated uptake of trospium in vitro. But it is a weak inhibitor of OCT2 transporter (IC50 = 482 ± 105 µM). Using FDA and EMA in vitro to in vivo extrapolation models, ranitidine was predicted to have a potential inhibition effect on intestinal OCT1 ([I]2/IC50 ~40), renal MATE1 ([I]1/IC50 ~0.02) and MATE2-K ([I]1/IC50 ~0.1) transporters in vivo. Clarithromycin was predicted to cause DDI by inhibiting P-gp-mediated efflux of trospium at the intestine ([I]2/IC50 of ~310) and hepatocytes ([I]3/IC50 ~1). Therefore, co-medication of oral clarithromycin was expected to result in an increase in oral absorption and hepatic clearance of trospium but not changes in distribution volume.
In healthy subjects, oral trospium is slowly (MAT ~10 h) and poorly (F ~10 %) absorbed from the jejunum and cecum/ascending colon, widely distributed into the body (Vss = 5 - 6 l/kg) and slowly eliminated (t1/2 = 9 - 10 h) majorly via renal glomerular filtration and tubular secretion (CLR ~500 ml/min). After co-medication of clarithromycin (inhibitor of P-gp), on the contrary to our IVIVE prediction, we found a non-expected but significant expansion of the shallow and deep distribution spaces for trospium by ~27 %. A single dose administration of trospium with co-medication of ranitidine (inhibitor of OCT1) resulted in no effect on the intestinal absorption of trospium. But the renal clearance of trospium decreased slightly (15 %) but significantly.
Intravenously administered trospium (2 mg TC) might be a suitable probe drug to evaluate the effects of a P-gp inhibitor on distribution of a drug. Oral trospium chloride can be selected for DDI studies with new chemical entities (NCE) with predicted inhibitory potential on OCT1 and P-gp and which are available after oral absorption along the small intestine and in the cecum/ascending colon. Another kind of application of trospium chloride might be pharmacogenomics studies in subjects with functionally relevant polymorphisms of P-gp and OCT1 or in patients with suspected transport failure due to intestinal diseases. The function of the efflux transporters MATE1 and MATE2-K in the PTC of the kidneys can be well assessed with the probe drug trospium by measuring its renal clearance.
The aim of the present dissertation was to investigate the biological and chemical potential of two European mushroom species: Fomitopsis betulina and Calvatia gigantea. For this purpose, different extracts of both fungi were tested for: antimicrobial, antifungal, cytotoxic, in vitro wound healing, and anti-adhesive properties. Bioassay-guided fractionation led to the isolation of bioactive compounds, altogether 20 compounds were isolated and identified. The compounds were obtained from the ethyl acetate extracts, they included triterpenes, sterols and aromatic compounds. The separated substances from both fungi were proved for biological activities, some of them showed antimicrobial and cytotoxic activities.
Infections with Helicobacter pylori are a global challenge that affects both developed and developing countries. This infection is currently treated using multiple antimicrobials that are mostly absorbed after oral administration and subsequently secreted into the gastric lumen. The eradication rates from the different therapeutic regimens, however, are declining nowadays, primarily due to high antibiotic resistance and possibly the mode of drug delivery. H. pylori is commonly found adhering to epithelial cells, and therefore, intragastric drug delivery may be a more direct treatment option. In this work, we developed a new strategy for the local eradication of H. pylori within the stomach.
Initial in vitro experiments revealed that penicillin G shows promising antibiotic activity against resistant strains of H. pylori with MIC values of 0.125 µg/mL. To provide luminal concentrations above the MIC for an extended time, we decided to follow two different formulation strategies: effervescent granules and HPMC-based hydrogel matrix tablets. Among the granule formulations, only one batch was stable and demonstrated excellent performance with respect to drug content, effervescent action, and drug release. It was therefore selected for further in vitro studies. All matrix tablets showed the desired tablet quality requirements and drug release was scalable in vitro by the HPMC concentration.
In order to quantify PGS in various formulations and media, an HPLC method was developed and validated. Due to the stability concerns, the degradation behavior of PGS was studied at different pH. PGS was found to be unstable at acidic pH values, but its stability was higher at more neutral pH values. Sufficient stability was exhibited at pH values above pH 4.5. Due to the instability of PGS in acidic media, alkalizers were added to the matrix tablets to prevent the degradation of the drug within the tablet. Among the alkalizers tested, NaHCO3 showed the most promising results as it significantly enhanced the stability within the matrix and also the concentration of PGS in the dissolution media. The stabilizing effect was caused mainly by the modulation of the microenvironmental pH rather than a pH change in the dissolution media. As a result, these matrix tablets were selected for further in vitro characterization.
In order to guide formulation development, a flow-through model (FTM), which was able to simulate various physiological conditions of the gastric environment, was developed and applied. In contrast to compendial dissolution methods, the FTM allowed studying the effect of gastric secretion, mixing and emptying on the gastric concentration of the drug in vitro. It could be shown that the granules generated a high initial concentration, which decreased over time. On the contrary, the matrix tablets did not provide such a profile due to the absence of pressure events in the model. Further investigations of the matrix tablets in a dissolution stress test device revealed faster drug release if pressure events of physiological relevance are simulated.
In the last part of this thesis, the two formulation concepts were compared in vivo by using the salivary tracer technique. For this purpose, caffeine was used as a model drug. The in vivo investigations suggested that granules administered in a fed state demonstrated longer gastric retention than in a fasted state. In a fed state, effervescent granules provided longer gastric retention of caffeine in comparison to the matrix tablets. Interestingly, the administration of the granules together with 240 mL of tap water provided an even better gastric retention of caffeine than the smaller volume (20 mL). Additional MRI investigations after 4 h of tablets’ intake revealed that the matrix tablets were already disintegrated in vivo.
In conclusion, effervescent granules dosed after food are expected to better maintain intragastric drug concentration over an extended period compared to matrix tablets. Moreover, the carbon dioxide generated after disintegration supports the mixing of the drug with the chyme and thus, provides a uniform distribution of the drug. By this, bacterial sanctuary sites within the stomach can be avoided. The major challenge could be the stability of PGS in acidic media. This problem could be addressed via concomitant administration of PPIs. H2 blockers could also be recommended to address nocturnal acid-breakthrough during the mid-night. In combination with an acid-reducing agent, PGS granule formulations alone or part of the treatment regimens could enable the local eradication of H. pylori directly within the stomach.
Humans consume snail flesh as part of their diet. To assess its nutritional value and toxicity, chemical analyses were conducted to confirm the presence of protein, total and reduced carbohydrates, fat, fatty acid composition and mineral components. Furthermore, an acute toxicity study was carried out to determine the safety of Helix aspersa Müller snail flesh. H. aspersa Müller snail flesh exhibits a high nutritional content, a good ω3/ω6 ratio and higher levels of unsaturated fatty acids. Various minerals have been found in the flesh of H. aspersa Müller. Around 76.91 kcal, or 3.84% of the energy of a daily meal of 2000 kcal, are present in 100 g of this flesh. The evaluation of the antioxidant capacity indicated that the flesh’s extracts contained a large quantity of antioxidant biomolecules. Administration of the aqueous extract of H. aspersa Müller flesh didn’t cause death in laboratory rats, indicating that the lethal dose 50 is greater than 2000 mg·kg−1 body weight. The consumption of the flesh of H. aspersa Müller is highly recommended for human consumption due to its high concentration of nutrients and essential elements, as well as unsaturated fats, and due to its safety.
Analysis and Reduction of Cellular Heterogeneity in Strain Optimization of Bacillus licheniformis
(2021)
Bacillus species invest substantial resources in inherent cellular processes for pre-adaptation to environmental changes, many of which are dispensable in the controlled environment of industrial bioprocesses. The underlying physiological mechanisms are well characterized in B. subtilis, but only little is known about these processes in the closely related B. licheniformis. Moreover, experimental conditions in previous studies differ from industrial settings in most parameters, foremost in batch cultures or plate-based analysis over fed-batch processes. In this thesis, cellular heterogeneity was analyzed in B. licheniformis in optimized, nutrient-rich media in batch and fed-batch cultivations. Systematic inactivation of genes involved in biofilm formation and synthesis of the flagellar apparatus or global regulators thereof resulted in higher protein production and provided new insights into biofilm formation and cellular heterogeneity in this strain.
The EyeFlowCell: Development of a 3D-Printed Dissolution Test Setup for Intravitreal Dosage Forms
(2021)
An in vitro dissolution model, the so-called EyeFlowCell (EFC), was developed to test intravitreal dosage forms, simulating parameters such as the gel-like consistency of the vitreous body. The developed model consists of a stereolithography 3D-printed flow-through cell with a polyacrylamide (PAA) gel as its core. This gel needed to be coated with an agarose sheath because of its low viscosity. Drug release from hydroxypropyl methylcellulose-based implants containing either triamcinolone acetonide or fluorescein sodium was studied in the EFC using a schematic eye movement by the EyeMovementSystem (EyeMoS). For comparison, studies were performed in USP apparatus 4 and USP apparatus 7. Significantly slower drug release was observed in the PAA gel for both model drugs compared with the compendial methods. Drug release from fluorescein sodium-containing model implants was completed after 40 min in USP apparatus 4, whereas drug release in the gel-based EFC lasted 72 h. Drug release from triamcinolone acetonide-containing model implants was completed after 35 min in USP apparatus 4 and after 150 min in USP apparatus 7, whereas this was delayed until 96 h in the EFC. These results suggest that compendial release methods may overestimate the drug release rate in the human vitreous body. Using a gel-based in vitro release system such as the EFC may better predict drug release.
Synthesis and evaluation of pseudosaccharin amine derivatives as potential elastase inhibitions
(2006)
Elastase is a serine protease which by definition is able to solubilize elastin by hydrolytic cleavage.Human Leukocyte Elastase, HLE (EC 3.4.21.37), is involved in deseases such as adult respiatory distress syndrome, pulmonary emphysema, smoking related chronic bronchitits, ischemic-reperfusion injury and rheumatoid arthritis. Hence, the elastase inhibitors have clinical utility in these diseases. Heterocyclic compounds are one of the most important classes of the elastase inhibitiors. In the present work different pseudosaccharin amine derivatives were synthesized and tested against the elastase. The synthesis of pseudosaccharin amine dervatives was carried out from the amines and(1,1-dioxobenzo[d]isothiazol-3-ylsulfanyl)acetonitrile in different solvents. Futhermore, the pseudosaccharin amines were obtained by refluxing the thiosaccarinates in absolute acetic acid. The reaction of 3-ethoxybenzo[d]isothiazole 1,1-dioxide with different amines in dioxane under reflux resulted into the desired pseudosaccharin amine derivatives in higher yields. Pseudosaccharin chloride was also used in the synthesis of these derivatives.A detail study of the synthesis of pseudosaccharin amine dervatives from the above differnt routes is described. Peptides were also synthesized by using the mixed anhydride method. The ester, acid, amide and peptide derivatives were tested against the Porcine Pancreatic Elastase (PPE) and Human Leukocyte Elastase (HLE). The esters were found to be the reversible inhibitors of HLE. The process of the PPE inhibion by cyanomethyl(2S)-2-(1,1-dioxobenzo[d]isothiazol-3-ylamino)-3-methylbutanoate was studied. Michaelis-Menten curve and Lineweaver-Burk double reciprocal plot were constructed in order to study the kinetic of this reaction. The compounds showing high inhibition of HLE were further stuied for determination of their inhibitory constant(Ki). The esters were found to be the higly active compounds against HLE. The cyanomethyl(2S)-2-(1,1-dioxobenzo[d]isothiazol-3-ylamino)-3-methylbutanoate and cyanomethyl(2S,3S)-2-(1,1-dioxobenzo[d]isothiazol-3-ylamino)-3-methylpentanoate showed the competitive reversible inhibition of HLE.The cyanomethyl(2S,3S)-2-(1,1-dioxobenzo[d]isothiazol-3-ylamino)-3-methylpentanoate is highly potent inhibitor of HLE. The possible mechanism of inhibition of elastase by these compounds is discussed. Molecular modelling of some of the ester derivatives is also discussed.
The use of digital tools can positively impact higher education for both scholars and faculty. In recent years, it has become apparent that podcasts are a suitable medium for use in teaching. They are provided almost exclusively by lecturers for students, with students passively listening to them rather than actively participating in their production. However, this could also be valuable for students. Therefore, this pilot study investigated the extent to which the creation of a podcast would be accepted by students as a method for capturing pharmacy students’ understanding of the learning content. The evaluation was performed as part of the “Clinical Chemistry” practical course, which was attended by third-year pharmacy students in groups of three. After passing the station dealing with practical clinical chemistry relevant diagnostic systems, the groups were asked to produce an educational podcast covering the essential content on the topics of urine test strips or pulse oximetry, respectively. Student attitudes toward the adoption of podcasts as a tool for performance assessment were determined with an anonymous and voluntary survey. The respondents reported that they had fun creating the podcast, which enabled them to look at the instructional content from a different perspective. Competencies such as social and communication skills and media literacy as well as self-organized and self-directed learning were also promoted. However, the students assumed that the tool is not ideally suited for dealing with extensive topics. Nonetheless, the students clearly support the continued creation of podcasts as a performance assessment tool. In addition, they suggest integrating podcasts into other courses within the pharmacy curriculum. This may also be related to the infrequent use of novel technologies, such as podcasts, in their education thus far.
Pharmaceutical residues are found in increasing concentrations in the environment and in potable water where they have verifiable effects on aquatic life. Conventional methods for water treatment are not able to sufficiently abate these generally stable compounds. It was found that physical plasma generated directly in water can degrade several of these recalcitrant organic pollutants. Studies on the basic plasma chemical processes for the model system of phenol showed that the degradation is primarily caused by hydroxyl radicals. This was confirmed by reaction chemistry and spin trap enhanced electron paramagnetic resonance spectroscopy (EPR). The degradation of diclofenac and its by-products were investigated in detail to perform a first risk-assessment of the new technology. Findings are not limited to the application of plasma but applicable to other advanced oxidation processes (AOP) that are based on the generation of hydroxyl radicals as well. Additionally, pulsed corona plasma and pulsed electric fields were assessed for their capacity to kill Legionella pneumophila in water. Whereas it was possible to kill L. Pneumophila with both methods, plasma treatment resulted in an enhanced bacterial killing. Therefore, advanced oxidation processes (AOP) and plasma treatment in particular are some of the few feasible approaches to decompose recalcitrant compounds in water.
There is a growing interest in the application of non-thermal atmospheric pressure plasma for the treatment of wounds. Due to the generation of various ROS and RNS, UV radiation and electric fields plasma is a very promising tool which can stimulate skin and immune cells. However, not much is known about the mammalian cell responses after plasma treatments on a molecular level. The present work focusses on the impact of plasma on cell signaling in the human keratinocyte cell line HaCaT by using the methods DNA microarray, qPCR, ELISA and flow cytometry. Here, cell signaling mediators such as cytokines and growth factors which could promote wound healing by enhancing angiogenesis, reepithelization, migration and proliferation were of major interest. Additionally, the crosstalk between keratinocytes and monocytes was studied using a co-culture. For the first time extensive investigations on the impact of plasma on cell signaling in human keratinocytes were conducted. The most prominent cytokines and growth factors which were regulated by plasma at gene and protein level were VEGF-A, GM-CSF, HB-EGF, IL-8, and IL-6. The latter was not activated due to the JAK/STAT-pathway but probably by a combined activation of MAPK- and PI3K/Akt-pathways. By the use of conditioned medium it was found out that ROS and RNS generated directly after plasma treatment induced larger effects on cell signaling in keratinocytes than the subsequently secreted growth factors and cytokines. Furthermore, monocytes and keratinocytes hardly altered their secretion profiles in co-culture. From these results it is deduced that the plasma generated reactive species are the main actors during cell signaling. In order to differentiate the impact of ROS and RNS on the cellular response the ambience of the plasma effluent was controlled, varying the ambient gas composition from pure nitrogen to pure oxygen. Thereby a first step towards the attribution of the cellular response to specific plasma generated reactive species was achieved. While IL-6 expression correlated with ROS generated by the plasma source, the cell signaling mediators VEGF-A, GM-CSF and HB-EGF were significantly changed by RONS. Above all hydrogen peroxide was found to play a dominant role for observed cell responses. In summary, plasma activates wound healing related cell signaling mediators as cytokines and growth factors in keratinocytes. It was also shown that the generated reactive species mainly induced cell signaling. For the first time cell responses can be correlated to ROS and RONS in plasma treated cells. These results underline the potential of non-thermal atmospheric pressure plasma sources for their applications in wound treatment.
For the characterization of Kv7.2/3 channel activators, several analytical methods are available that vary in effort and cost. In addition to the technically elaborate patch-clamp method, which serves as a reference method, there exist several medium to high-throughput screening methods including a rubidium efflux flame-atomic absorption spectrometry (F-AAS) assay and a commercial thallium uptake fluorescence-based assay. In this study, the general suitability of a graphite furnace atomic absorption spectrometry (GF-AAS)-based rubidium efflux assay as a screening method for Kv7.2/3 channel activators was demonstrated. With flupirtine serving as a reference compound, 16 newly synthesizedcompounds and the known Kv7.2/3 activator retigabine were first classified as either active or inactive by using the GF-AAS-based rubidium (Rb) efflux assay. Then, the results were compared with a thallium (Tl) uptake fluorescence-based fluorometric imaging plate reader (FLIPR) potassium assay. Overall, 16 of 17 compounds were classified by the GF-AAS-based assay in agreement with their channel-activating properties determined by the more expensive Tl uptake, fluorescence-based assay. Thus, the performance of the GF-AAS-based Rb assay for primary drug screening of Kv7.2/3-activating compounds was clearly demonstrated, as documented by the calculated Z’-factor of the GF-AAS-based method. Moreover, method development included optimization of the coating of the microtiter plates and the washing procedure, which extended the range of this assay to poorly adherent cells such as the HEK293 cells used in this study.
Livestock animals, especially poultry, are a known reservoir for extended-spectrum beta-lactamase (ESBL)-producing Escherichia coli (E. coli). They may enter the pen either via positive day-old chicks or via the environment. We developed a mathematical model to illustrate the entry and dissemination of resistant bacteria in a broiler pen during one fattening period in order to investigate the effectiveness of intervention measures on this infection process. Different management measures, such as varying amounts of litter, a slow-growing breed or lower stocking densities, were tested for their effects on broiler colonization. We also calculated the impact of products that may influence the microbiota in the chicks’ digestive tract, such as pre- or probiotics, feed supplements or competitive exclusion products. Our model outcomes show that a contaminated pen or positive chicks at the beginning of the fattening period can infect the entire flock. Increasing the amount of litter and decreasing the stocking density were shown to be effective in our model. Differences in the route of entry were found: if the chicks are already positive, the litter quantity must be increased to at least six times the standard of 1000 g/m2, whereas, if the pen is contaminated on the first day, three times the litter quantity is sufficient. A reduced stocking density of 20 kg/m2 had a significant effect on the incidence of infection only in a previously contaminated pen. Combinations of two or three measures were effective in both scenarios; similarly, feed additives may be beneficial in reducing the growth rate of ESBL-producing E. coli. This model is a valuable tool for evaluating interventions to reduce the transmission and spread of resistant bacteria in broiler houses. However, data are still needed to optimize the model, such as growth rates or survival data of ESBL-producing E. coli in different environments.
In recent years, the colon has become a hot topic in biopharmaceutical research as several in vitro models of the human colon have been presented. A major focus is on the characterization of the microbiota and its capabilities. The aim of the present study was to further develop the MimiCol, preserving its properties and accelerating data acquisition. Emphasis was placed on the simplicity of its design and easy scalability. To prove the viability of the concept, degradation of sulfasalazine was investigated, and the bacterial composition during the experiment was assessed by 16S rRNA sequencing. The transfer of the experimental conditions to the new model was successful. Commercially available components were implemented in the setup. The model MimiCol3 represented the colon ascendens satisfactorily in its properties regarding volume, pH value, and redox potential. 16S rRNA sequencing led to further insights into the bacterial composition in the vessels. Degradation of sulfasalazine was in good agreement with in vivo data. The new model of the colon ascendens MimiCol3 enabled us to collect more reliable data, as three experiments were conducted simultaneously under the same conditions.
The role of glutathione peroxidases (GPx) in cancer and their influence on tumor prognosisand the development of anticancer drug resistance has been extensively and controversially discussed.The aim of this study was to evaluate the influence of GPx1 expression on anticancer drug cytotoxicity.For this purpose, a GPx1 knockout of the near-haploid human cancer cell line HAP-1 was generatedand compared to the native cell line with regards to morphology, growth and metabolic rates,and oxidative stress defenses. Furthermore, the IC50values of two peroxides and 16 widely usedanticancer drugs were determined in both cell lines. Here we report that the knockout of GPx1 in HAP-1cells has no significant effect on cell size, viability, growth and metabolic rates. Significant increasesin the cytotoxic potency of hydrogen peroxide andtert-butylhydroperoxide, the anticancer drugscisplatin and carboplatin as well as the alkylating agents lomustine and temozolomide were found.While a concentration dependent increases in intracellular reactive oxygen species (ROS) levelswere observed for both HAP-1 cell lines treated with either cisplatin, lomustine or temozolamide,no significant enhancement in ROS levels was observed in the GPx1 knockout compared to the nativecell line except at the highest concentration of temozolamide. On the other hand, a ca. 50% decreasein glutathione levels was noted in the GPx1 knockout relative to the native line, suggesting thatfactors other than ROS levels alone play a role in the increased cytotoxic activity of these drugs in theGPx1 knockout cells.
In den Weltmeeren findet rund die Hälfte der jährlichen globalen Kohlenstofffixierung statt, davon ein großer Anteil in küstennahen Regionen. Hier kommt es zu wiederkehrenden saisonalen Algenblüten, die durch eine zeitlich begrenzte explosionsartige Vermehrung von Mikroalgen (hauptsächlich Diatomeen und Coccolithophoren) charakterisiert sind. Vor allem Frühjahrsblüten (März-Mai) haben aufgrund ihrer zeitlichen und räumlichen Vorhersagbarkeit einen hohen Stellenwert als Modellsysteme, anhand deren sich der Kohlenstoffkreislauf der Meere untersuchen lässt.
Mikroalgen produzieren eine große Vielfalt an Makromolekülen, die für die mit ihnen vergesellschafteten Bakterien als Nahrungsgrundlage dienen. Besonders im Fokus stehen hier die für den Kohlenstoffkreislauf relevanten Polysaccharide. Im Gegensatz zu anderen natürlichen Makromolekülen wie DNA oder Proteinen können Polysaccharide aus vielen verschiedenen Monomeren mit unterschiedlichsten Bindungen bestehen. Zusätzlich finden sich an diesen Zuckermonomeren viele Modifikationen wie Acetylierungen, Methylierungen oder Sulfatierungen, die die Komplexität weiter erhöhen. Diese Variabilität bedingt eine hohe strukturelle und funktionale Diversität. So können Polysaccharide Speicherstoffe, Zellwandbestandteile oder Teile der extrazellulären Matrix darstellen.
Komplementär hierzu besitzen Polysaccharid-verwertende Bakterien entsprechend komplexe, enzymatische Abbaumechanismen. Besonders hervorzuheben sind hier die Bakterien des Phylums Bacteroidota, die sich in verschiedensten Nischen auf den Abbau von Polysacchariden spezialisiert haben. Sie finden sich in Bodenproben, als Teil der menschlichen Darmflora, oder eben auch als bedeutende Begleiter von Algenblüten.
Bacteroidota (und in marinen Systemen hauptsächlich die zu ihnen gehörenden Flavobakterien) besitzen zum Abbau diverser Polysaccharide sogenannte Polysaccharide utilization loci (PULs), genomische Inseln, die alle notwendigen Proteine zur Aufnahme und Abbau eines bestimmten Polysaccharids codieren. Hierzu gehören hochspezifische Enzyme (Carbohydrate-active enzymes, CAZymes), transkriptionelle Regulatoren sowie Transportersysteme, die initial gespaltene Oligosaccharide über die Membran in das Bakterium transportieren, wo sie von weiteren Enzymen vollständig abgebaut werden. Diese Co-Lokalisation der benötigten Gene und deren gemeinsame Regulation stellt einen enormen Selektionsvorteil der Bacteroidota dar und ist der Grund, warum sie, ähnlich wie Algen, einer jährlich wiederkehrenden Sukzession folgen, die sich gut untersuchen lässt.Die Forschungsartikel, die Teil dieser Doktorarbeit sind, untersuchen das Zusammenspiel von Polysaccharid-produzierenden Algen mit den Bakterien, die sie abbauen, aber auch darauf basierende Beziehungen der Bakterien untereinander. Die erste Publikation beschäftigt sich mit dem weit verbreiteten Speicherpolysaccharid α-Glucan, für das der Großteil der blütenbegleitenden Bakterien einen spezifischen aktiven PUL besitzt. Eine Untersuchung der in der Blüte vorhandenen Algenarten bestätigte, dass die Blüte von β-Glucan-produzierenden Algen dominiert wird. Da Bakterien aber selbst α-Glucane als Speicherpolysaccharide verwenden, konnte gezeigt werden, dass nicht die Algen selbst, sondern die Bakterien Hauptproduzent dieser Polysaccharide während einer Phytoplanktonblüte sind. Bakterielle Proteine, die dem Abbau von Algen-β-Glucan und dem daraus folgenden Aufbau von bakteriellem α-Glucan dienen, waren in Umweltproben und in Laborkulturen unter ähnlichen Bedingungen abundant. Die Untersuchung von extrahiertem bakteriellem Polysaccharid bewies, dass dieses nicht nur α-Glucan enthält, sondern dass dieses Polysaccharid auch in der Lage war, α-Glucan PULs mariner Bakterien zu induzieren. Hier zeigte sich ein innerhalb des marinen Kohlenstoffkreislaufs bisher wenig berücksichtigter Kreislauf, indem Bakterien Polysaccharide anderer Bakterien nutzen, die z.B. durch Viren lysiert wurden.
Die anderen zwei Artikel dieser Arbeit befassen sich mit dem Abbau von Zellwandpolysacchariden durch blütenassoziierte Modellbakterien. In einer der Studien wird detailliert der Abbau eines β-Mannans (ein Polysaccharid das hauptsächlich aus dem Monosaccharid Mannose besteht) durch ein Bakterium des Genus Muricauda beschrieben. Die PUL-Struktur dieses Bakteriums kam in mehreren anderen Phytoplanktonblüten-assoziierten Bakterien vor. Diese Beobachtung wies darauf hin, dass es sich hier um ein Mannan mit zusätzlichen Galactose- und Glucose-Substitutionen handelte. Proteom-Untersuchungen bestätigten, dass das Bakterium derartige Substrate unter Induktion des β-Mannan-PULs nutzen können. β-Mannan konnte durch Antikörpermarkierung in Blütenproben sowie spezifischen Mikroalgenarten (Chaetoceros, Coscinodiscus) nachgewiesen werden. Die in dieser Publikation charakterisieren β-Mannan-PUL-codierten Enzyme waren in der Lage, dieses Signal zu löschen, was bewies, dass Muricauda sp. Mannan-basierte Zellwandpolysaccharide bestimmter Arten von Mikroalgen abbauen kann.
Die dritte Studie geht näher auf den Abbau von Xylanen (bestehend aus Xylose) durch ein blütenassoziiertes Bakterium des Genus Flavimarina ein. In diesem Bakterium wurden anhand der enthaltenen Xylanasen zwei putative Xylan-PULs annotiert. Wachstumsexperimente und Proteom-Untersuchungen zeigten, dass einer dieser PULs hauptsächlich bei Wachstum auf Glucoronoxylan induziert wird, während der andere PUL aufArabinoxylane stärker reagierte. Untersuchung der PUL-CAZymes bestätigte diese Ergebnisse durch Charakterisierung mehrerer Xylanasen sowie Glucoronidasen und Arabinofuranosidasen. Zusätzlich codierten beide PULs für Esterasen, die eine Modifikation der natürlichen Substrate durch Acetylierungen oder Methylierungen nahelegen. Da all diese Merkmale von terrestrischen Xylanen geteilt werden und in Blütenproben aus Küstennahen Regionen Xylane nachgewiesen wurden, ist es möglich, dass Bakterien aus solchen Regionen sowohl Xylane terrestrischen Ursprungs (z.B. durch Flusseinspeisung) sowie marinen Ursprungs abbauen können.
The polysaccharide β-mannan, which is common in terrestrial plants but unknown in microalgae, was recently detected during diatom blooms. We identified a β-mannan polysaccharide utilization locus (PUL) in the genome of the marine flavobacterium Muricauda sp. MAR_2010_75. Proteomics showed β-mannan induced translation of 22 proteins encoded within the PUL. Biochemical and structural analyses deduced the enzymatic cascade for β-mannan utilization. A conserved GH26 β-mannanase with endo-activity depolymerized the β-mannan. Consistent with the biochemistry, X-ray crystallography showed the typical TIM-barrel fold of related enzymes found in terrestrial β-mannan degraders. Structural and biochemical analyses of a second GH26 allowed the prediction of an exo-activity on shorter manno-gluco oligosaccharides. Further analysis demonstrated exo-α-1,6-galactosidase- and endo-β-1,4-glucanase activity of the PUL-encoded GH27 and GH5_26, respectively, indicating the target substrate is a galactoglucomannan. Epitope deletion assays with mannanases as analytic tools indicate the presence of β-mannan in the diatoms Coscinodiscus wailesii and Chaetoceros affinis. Mannanases from the PUL were active on diatom β-mannan and polysaccharide extracts sampled during a microalgal bloom at the North Sea. Together these results demonstrate that marine microorganisms use a conserved enzymatic cascade to degrade β-mannans of marine and terrestrial origin and that this metabolic pathway plays a role in marine carbon cycling.
Flupirtine and retigabine were essential drugs to combat pain and epilepsy. However, the Kv7 potassium channel openers are fraught with hepatotoxicity and tissue discoloration, respectively, limiting their therapeutic value. Both adverse events are likely due to reactive metabolites arising from oxidative metabolism. Designing safer analogues lacking the structural elements leading to described side effects is an active area of current research. One of the main metabolites of flupirtine is the biologically inactive 4-fluorohippuric acid. Hitherto unexplained, the proposed metabolic pathway leading to the formation of 4-fluorohippuric acid from flupirtine is verified here. Through the use of eighteen flupirtine analogues, mechanistic details of this pathway could be elucidated. A possible connection with the in vitro hepatotoxicity of the flupirtine analogues and the levels of 4-fluorobenzoic acid formed in enzyme incubations was examined by correlation analysis. These findings provide important information for the design of new flupirtine analogues as potential drug candidates.
Development of Test Programs for the Biorelevant Characterization of Esophageal-Applied Dosage Forms
(2023)
In the local treatment of the esophageal mucosa, the retention time of the different dosage forms, such as tablets, films or liquids, is of high relevance for the effective treatment of diseases. Unfortunately, there are only few in vitro models describing the esophageal route of administration. To predict the behaviour of an esophageal-applied dosage form, it is necessary to simulate the site of application in a biorelevant way. The aim of this work was to develop two test setups for an esophageal peristalsis model which was described in a previous study. Different parameters such as flow rate, peristalsis, angle of inclination or mucous membrane were varied or introduced into the model. A stimulated and unstimulated modus were developed and tested with two different dosage forms. The time until the dosage form was cleared from the in vitro model was shorter with the stimulated than with the unstimulated modus. Also, esophageal-applied films had a prolonged transit time compared to a viscous syrup. The modification of the simulated esophageal surface made it possible to estimate the retention time of the dosage forms. It could be demonstrated that the residence time of a dosage form depends on different parameters affecting each other.
Abstract
Aim
To verify synergistic effects, we investigated the antimicrobial activity of seven phenolic phytochemicals (gallic acid; epicatechin; epigallocatechin gallate; daidzein; genistein; myricetin; 3‐hydroxy‐6‐methoxyflavone) in combination with six antibiotics against multidrug‐resistant isolates from the ESKAPE group.
Methods and Results
To investigate single phytochemicals and combinations, initial microdilution and checkerboard assays were used, followed by time‐kill assays to evaluate the obtained results. The research revealed that phenolic compounds on their own resulted in little or no inhibitory effects. During preliminary tests, most of the combinations resulted in indifference (134 [71.3%]). In all, 30 combinations led to antagonism (15.9%); however, 24 showed synergistic effects (12.8%). The main tests resulted in nine synergistic combinations for the treatment of four different bacteria strains, including two substances (3‐hydroxy‐6‐methoxyflavone, genistein) never tested before in such setup. Time‐kill curves for combinations with possible synergistic effects confirmed the results against Acinetobacter baumannii as the one with the greatest need for research.
Conclusions
The results highlight the potential use of antibiotic–phytocompound combinations for combating infections with multi‐resistant pathogens. Synergistic combinations could downregulate the resistance mechanisms of bacteria.
Significance and Impact of the Study
The aim of this study is to demonstrate the potential use of phenolic natural compounds in combination with conventional antibiotics against multidrug‐resistant bacteria of the ESKAPE group. Due to synergistic effects of natural phenolic compounds combined with antibiotics, pathogens that are already resistant to antibiotics could be resensitized as we were able to reduce their MICs back to sensitive. In addition, combination therapies could prevent the development of resistance by reducing the dose of antibiotics. This approach opens up the basis for future development of antimicrobial therapy strategies, which are so urgently needed in the age of multidrug‐resistant pathogens.
Multidrug-resistant gram-negative pathogens such as Escherichia coli have become increasingly difficult to treat and therefore alternative treatment options are needed. Targeting virulence factors like biofilm formation could be one such option. Inhibition of biofilm-related structures like curli and cellulose formation in E. coli has been shown for different phenolic natural compounds like epigallocatechin gallate. This study demonstrates this effect for other structurally unrelated phenolics, namely octyl gallate, scutellarein and wedelolactone. To verify whether these structurally different compounds influence identical pathways of biofilm formation in E. coli a broad comparative RNA-sequencing approach was chosen with additional RT-qPCR to gain initial insights into the pathways affected at the transcriptomic level. Bioinformatical analysis of the RNA-Seq data was performed using DESeq2, BioCyc and KEGG Mapper. The comparative bioinformatics analysis on the pathways revealed that, irrespective of their structure, all compounds mainly influenced similar biological processes. These pathways included bacterial motility, chemotaxis, biofilm formation as well as metabolic processes like arginine biosynthesis and tricarboxylic acid cycle. Overall, this work provides the first insights into the potential mechanisms of action of novel phenolic biofilm inhibitors and highlights the complex regulatory processes of biofilm formation in E. coli.
Transition metal complexes play a crucial role in antitumor therapy. Complexes of platinum, ruthenium as well as lanthanum and gallium have been investigated in preclinical as well as in clinical studies. The best known platinum(II) agents approved worldwide, cisplatin or carboplatin, are used in nearly 50% of all cancer therapies. This work focused on the development of new metal-based drugs that could act against human cancer cells. It was motivated in part by previous work with Cu(II) complexes, reporting new coordination compounds of SOD mimicking and cytotoxic activities. On the basis of this work we chose several commercially available heterocyclic ligands to synthesize new metal ion complexes in search of their interesting biological activity. New as well as previously reported Cu(II), Co(II), Pt(II) and Zn(II) complexes were synthesized using various ligands (1-6). Almost all chelating 2:1 ligand-metal complexes were obtained generally in water at room temperature in the reaction of metal(II) chloride with corresponding aromatic nitrogen ligands bearing an O-carboxylate group ligand. The synthesized chelating complexes were characterized by the use of spectroscopic methods, elemental analyses and HPLC chromatography and some by X-ray crystallography. Such coordination compounds are easily formed by transition metals with free orbitals d that can accept the donor electron pairs. The coordination is through the heterocyclic nitrogen and carboxylate oxygen donor atoms, which was shown by analysis of the characteristic functional groups in the IR spectra. The d-d transitions and absorption of visible light in Cu(II) and Co(II) complexes make them highly colored, blue, green or green-blue, respectively. The configuration of the coordination center was established in some cases by X-ray crystallography. Most of the already published structures possess the trans configuration. This led to the assumption that other uncrystallized complexes were also trans configured. However, X-ray data of the Cu(II) complex of 5 showed quite unexpectedly the cis configuration. On the other hand, the LC/MS experiments with the Pt(II) complex of 5 indicated that this complex exists in two isomeric forms, i.e., cis and trans at the Pt(II) center. Through the use of density functional calculations we optimized the structures and calculated the energies and dipole moments. The differences in energy for all complexes were about 6 to 15-fold lower when compared to cis and transplatin. The DFT calculations confirmed that the trans-isomers are more stable than their cis-isomers. UV-Vis stability studies with most of the synthesized complexes as well as some other Cu(II) complexes were performed to study the spectral changes over 24 h in addition of glutathione, a tripeptide present in the cancer cells and ascorbate that were added to the incubations. The results indicated time-dependent changes and instability of the complexes in the cells and their possible decomposition to lose the ligand and release the metal ion. In the case of Cu(II) complexes, reduction of Cu(II) to Cu(I) may take place. New species such as GSSG could arise and the complexes may decarboxylate, but these structures were not elucidated. The synthesized coordination metal(II) complexes were tested for their potential antiproliferative activities by using the crystal violet staining method in a panel of human cancer cell lines. Out of all complexes, three Pt(II) complexes of 2, 5 and 6 showed satisfactory activity and for these complexes the IC50 values were additionally determined in new RT-4, DAN-G and MCF-7 cancer cell lines. Interestingly, the active complexes were the chelating trans complexes which is quite unexpected, based on the difference in activities between cis and transplatin. All of the complexes were tested for their potential antimicrobial activities in comparison to the standard antibiotics on such bacterial strains as Staphylococcus aureus, Bacillus subtilis, Escherichia coli, Pseudomonas aeruginosa and yeast Candida maltosa. Co(II) complexes have been especially known to act against bacterial strains. The activity of the Co(II) complexes was indeed the highest of all metal(II) complexes. The ligand 2 (a nicotinic acid isomer) was also found active. This fact could explain why some antibacterial activity was found in the MIC assay. In addition to the complexes synthesized in this work, several novel heterocyclic metal(II) complexes of copper, ruthenium, platinum, gallium, osmium and lanthanum from other research groups were screened for their antiproliferative activity, some of which exhibited very potent activity in the cancer cell lines. In conclusion, Pt(II) complexes with bis-chelating heterocyclic carboxylate ligands represent a particularly interesting new class of compounds from the view point of their structural and biological properties.
In the search for new antifungal agents, this study dealt with the antimicrobial screening, extraction, isolation, structural elucidation as well as selective biological investigations of the isolated compounds. In addition, the impact of the culture conditions on growth and on biosynthesis of bioactive compounds was also studied. Besides, selective cyanobacteria were axenized and the taxonomy as well as the genetic relationship of axenic cyanobacteria that produced bioactive compounds with some other cyanobacteria was identified basing on the 16S rRNA gene sequences. 22 Vietnamese and 6 German cyanobacterial strains were screened for their antifungal activity using the agar diffusion assay. Among them, the MeOH/water extract from the biomass obtained from a laboratory culture of strain Bio 33, isolated from the Baltic Sea near Rügen Island, exhibited a specific antifungal activity against Candida maltosa and others human pathogenous fungi such as Candida albicans, Candida krusei, Aspergillus fumigatus, Microsporum gypseum, Trichophyton rubrum and Mucor sp. Besides, it was very impressed that extracts of strain Bio 33 showed no antibacterial activity against Escherichia coli, Pseudomonas aeruginosa, Bacillus subtilis, and Staphylococcus aureus. The taxonomy basing on 16S rRNA gene sequence of the axenic Bio 33 identified this strain as Anabaena cylindrica species. As a result of the bioassay-guided fractionation of the crude MeOH/water extract, four new lipopeptides, named balticidins A – D, were isolated. These lipopeptides represent a new structural type with the co-occurrence of a glycosylated cyclic peptide, a fatty acid containing chlorine and a disaccharide moiety. The main active fraction isolated from the MeOH/water extract of the biomass of Bio 33 which contains the four lipopeptides exhibited only marginal cytotoxic activity against the human bladder carcinoma cell line 5637 (IC50 = 93 μg/ml). The weak cytotoxic activity and the absence of antibacterial effects in the used in vitro test systems opens a promising future for further investigations to clarify the antifungal mechanism and for in vivo applications of the new lipopeptides. Different media, temperature, light intensity and period of irradiance, the depletion of nitrate and the trace element cobalt were investigated to figure out conditions at which Bio 33 produces maximum of balticidins under laboratory conditions. Temperature was the most apparent factor influencing the growth of Bio 33 and the production of balticidins. Bio 33 grew best in BG 11 medium plus 0.5% NaCl at 26°C, under white fluorescent continuous light and a light intensity of 20 μmol photons m-2 s-1. Nevertheless, under the same conditions, 22.5°C was the best temperature for the production of balticidins. Besides, harvesting of Bio 33 during the logarithmic growth phase, particularly at 20th day, should supply approximately maximum quantity of balticidins. At 22.5°C and 20 μmol photons m-2 s-1 under 24 h continuous irradiance, the depletion of nitrate had no negative effect on the growth and concentration of balticidin A but increased balticidin B and decreased balticidin C; the absence of cobalt slightly decreased the growth but had no clear effect on the production of balticidins. On the other hand, extracts of the culture medium of the Vietnamese cyanobacterium TVN40, exhibited antifungal activity against Candida maltosa and weak antibacterial activity. Extraction of the culture medium with XAD-16 and elution of the XAD-bounded compounds by different solvents resulted in five fractions (water, 80% MeOH, 100% MeOH, acetone, dichloromethan). Four compounds have been isolated from the 80% MeOH fraction and one was identified as a dioxindole derivative. Structural elucidation of the other three compounds is still in progress. TVN40 was formerly identified as an Anabaena sp. according to the morphological properties, but the 16S rRNA gene sequence confirms that the strain belongs to the genus Nostoc. Microscopic examination of TVN40 revealed that the filamentous strain was not a unialgal but a mixed culture with strange round cells (SRCs) - a unicellular cyanobacterium belonging to the order Chroococcales. Laboratory cultures of the pure filamentous strain TVN40, the isolated SRCs and the mixed culture of both strains were established. Both TVN40 and SRC culture media were responsible for the antibacterial activity against B. subtilis, S. aureus and E. coli. However, only the extract of the culture medium of TVN40 was active against C. maltosa. The supplement of cobalt enhanced the antimicrobial activity of the culture medium. Pure strains showed higher activity in comparison to the mixed culture of TVN40 and SRC.
Non-thermal atmospheric pressure plasma has drawn more and more attention to the field of wound healing research during the last two decades. It is characterized by a unique composition, which includes amongst others free radicals, ions and electrons. Furthermore, non-thermal plasma exhibits temperatures that are below those inducing thermal cell damage. Next to its well-established anti-bacterial properties, plasma can have lethal as well as stimulating effects on mammalian cells. Therefore, the medical application of non-thermal plasma on chronic wounds seems to be a promising tool to enable healing processes. However, less is known about the plasma-mediated induction of intracellular signaling pathways in human immune cells, which play a leading part in the process of wound recovery and removal of pathogens. Therefore, this thesis examined the cellular effects of a non-thermal atmospheric pressure plasma treatment on human immune cells using the argon plasma jet kinpen 09. Here, the CD4+ T helper cell line Jurkat, the monocyte cell line THP-1 as well as the corresponding primary cells were investigated. First, cell survival and apoptosis induction was assessed in response to non-thermal plasma treatment by growth curves and flow cytometric assays. On the one hand it could be shown that primary cells are more susceptible to plasma treatment than the respective cell lines. On the other hand, monocytes responded less sensitive to plasma exposure than lymphocytes. Furthermore, this thesis outlined the impact of non-thermal plasma treatment on the gene expression level of immune cells. Therefore, DNA microarray analysis was performed with the cell lines Jurkat and THP-1. It became obvious that plasma exposure modulated the expression of several genes in both cell types. Differential expression of distinct target genes was further validated by quantitative PCR in the immune cell lines. Here, elevated gene expression levels of JUN and FOS in Jurkat cells and increased transcription of JUND in THP-1 cells in response to plasma treatment were made visible. JUN, FOS and JUND are components of the transcription factor AP-1, which is involved amongst others in gene expression of IL-8 and HMOX-1. Consequently, transcriptional induction of the inflammatory cytokine IL-8 as well as the enzymes HMOX-1 and GSR was detected in plasma-treated THP-1 cells. In addition, alterations in the protein activation levels were analyzed in plasma-treated Jurkat, THP-1 cells and primary monocytes. Since some of the identified target genes are known to be associated with the MAPK pathways, the regulation of these cascades was further investigated by western blot analysis. In all investigated cell types the pro-proliferative signaling molecules ERK 1/2 and MEK 1/2 as well as the pro-apoptotic signaling proteins p38 MAPK and JNK 1/2 were activated in a plasma treatment time dependent manner. In contrast to Jurkat and primary monocytes, the anti-apoptotic HSP27 was only induced in THP-1 cells in response to plasma exposure. Moreover, modulation of cytokine production and secretion was examined in the different immune cell types and co-cultured THP-1 and HaCaT keratinocytes by ELISA or flow cytometry. While Jurkat cells showed no plasma-mediated regulation of cytokine expression, THP-1 cells revealed an increased IL-8 secretion after long plasma time duration (360 s). Additionally, the intracellular expression levels of IL-6 and IL-8 were modulated in primary monocytes by plasma exposure. While short plasma treatment caused no alteration of the number of cells expressing IL-8 an up-regulation of the intracellular IL-6 level occurred after 30 s of plasma treatment. Long plasma treatment times resulted in a significant decrease of the intracellular IL-8 and IL-6 production levels. Furthermore, co-cultured THP-1 and HaCaT cells as well as mono-cultured THP-1 and HaCaT cells were examined regarding their cytokine secretion profile. Here, cells treated with plasma (180 s) as well as LPS and plasma (180 s and LPS) were compared with untreated cells. IL-6, IL-8 and GM-CSF secretion was induced by both plasma and plasma combined with LPS treatment in mono-cultivated HaCaT cells and co-cultured cells. Though, the highest cytokine secretion levels were reached in the plasma and LPS exposed co-culture. In contrast, mono-cultivated THP-1 cells only showed an increased secretion of IL-6, IL-8 and TNFa after incubation with plasma together with LPS exposed medium. In conclusion, this study revealed for the first time the non-thermal plasma-modulated expression of numerous genes and cytokines and the activation state of various signaling cascades in human immune cells. Thus, it contributes to gain a better understanding of the immune-modulatory impacts of plasma that might promote the wound healing process.
Essential Oils as Multicomponent Mixtures and Their Potential for Human Health and Well-Being
(2022)
Essential oils (EOs) and their individual volatile organic constituents have been an inherent part of our civilization for thousands of years. They are widely used as fragrances in perfumes and cosmetics and contribute to a healthy diet, but also act as active ingredients of pharmaceutical products. Their antibacterial, antiviral, and anti-inflammatory properties have qualified EOs early on for both, the causal and symptomatic therapy of a number of diseases, but also for prevention. Obtained from natural, mostly plant materials, EOs constitute a typical example of a multicomponent mixture (more than one constituent substances, MOCS) with up to several hundreds of individual compounds, which in a sophisticated composition make up the property of a particular complete EO. The integrative use of EOs as MOCS will play a major role in human and veterinary medicine now and in the future and is already widely used in some cases, e.g., in aromatherapy for the treatment of psychosomatic complaints, for inhalation in the treatment of respiratory diseases, or topically administered to manage adverse skin diseases. The diversity of molecules with different functionalities exhibits a broad range of multiple physical and chemical properties, which are the base of their multi-target activity as opposed to single isolated compounds. Whether and how such a broad-spectrum effect is reflected in natural mixtures and which kind of pharmacological potential they provide will be considered in the context of ONE Health in more detail in this review.
Marine Bacteroidetes that degrade polysaccharides contribute to carbon cycling in the ocean. Organic matter, including glycans from terrestrial plants, might enter the oceans through rivers. Whether marine bacteria degrade structurally related glycans from diverse sources including terrestrial plants and marine algae was previously unknown. We show that the marine bacterium Flavimarina sp. Hel_I_48 encodes two polysaccharide utilization loci (PULs) which degrade xylans from terrestrial plants and marine algae. Biochemical experiments revealed activity and specificity of the encoded xylanases and associated enzymes of these PULs. Proteomics indicated that these genomic regions respond to glucuronoxylans and arabinoxylans. Substrate specificities of key enzymes suggest dedicated metabolic pathways for xylan utilization. Some of the xylanases were active on different xylans with the conserved β-1,4-linked xylose main chain. Enzyme activity was consistent with growth curves showing Flavimarina sp. Hel_I_48 uses structurally different xylans. The observed abundance of related xylan-degrading enzyme repertoires in genomes of other marine Bacteroidetes indicates similar activities are common in the ocean. The here presented data show that certain marine bacteria are genetically and biochemically variable enough to access parts of structurally diverse xylans from terrestrial plants as well as from marine algal sources.
Metabolic engineering enables Bacillus licheniformis to grow on the marine polysaccharide ulvan
(2022)
Background
Marine algae are responsible for half of the global primary production, converting carbon dioxide into organic compounds like carbohydrates. Particularly in eutrophic waters, they can grow into massive algal blooms. This polysaccharide rich biomass represents a cheap and abundant renewable carbon source. In nature, the diverse group of polysaccharides is decomposed by highly specialized microbial catabolic systems. We elucidated the complete degradation pathway of the green algae-specific polysaccharide ulvan in previous studies using a toolbox of enzymes discovered in the marine flavobacterium Formosa agariphila and recombinantly expressed in Escherichia coli.
Results
In this study we show that ulvan from algal biomass can be used as feedstock for a biotechnological production strain using recombinantly expressed carbohydrate-active enzymes. We demonstrate that Bacillus licheniformis is able to grow on ulvan-derived xylose-containing oligosaccharides. Comparative growth experiments with different ulvan hydrolysates and physiological proteogenomic analyses indicated that analogues of the F. agariphila ulvan lyase and an unsaturated β-glucuronylhydrolase are missing in B. licheniformis. We reveal that the heterologous expression of these two marine enzymes in B. licheniformis enables an efficient conversion of the algal polysaccharide ulvan as carbon and energy source.
Conclusion
Our data demonstrate the physiological capability of the industrially relevant bacterium B. licheniformis to grow on ulvan. We present a metabolic engineering strategy to enable ulvan-based biorefinery processes using this bacterial cell factory. With this study, we provide a stepping stone for the development of future bioprocesses with Bacillus using the abundant marine renewable carbon source ulvan.
Marine bacteria represent the most diverse organisms in the marine environment. The majority of these microbes is unknown and unculturable. Algae represent the main nutrient source for bacteria. Macro- and microalgae can consist to 70% of polysaccharides. The metabolic degradation of marine polysaccharides is underexplored and thus these mechanisms have to be investigated. These mechanisms are of high importance to generate defined oligosaccharides for the medical and pharmaceutical applications. The specific structure of marine poly- and oligosaccharides show antiviral activities, e.g. carrageenans from red algae are used for the inhibition of human papillomavirus. Another alginate derived marine polysaccharide show inhibition of the replication of the human immunodeficiency virus (HIV). The degradation mechanisms of marine CAZymes and the structure of marine polysaccharides should be further investigated for their high potential of antiviral activities and the creation of new marine drugs.
Many marine bacteria produce membrane extension like membrane vesicles or appendages but the function of these is poorly understood. In order to investigate their function, especially concerning polysaccharide utilization, proteomic analyses of subcellular compartments were performed. Microscopy analyses revealed that, beside MV, P. distincta forms different appendages, vesicle chains (VC) and thin filaments which were dedicated to extracellular polymeric substance. The formation of MV and VC was independent of growth phase or carbon source. The proteomic data showed that transporters end enzymes for the initial degradation of pectin and alginate were highly abundant in these membrane extensions and that there could be a kind of sorting for proteins in the membrane extensions. Additionally, two PUL encoded alkaline phosphatases and other phosphate acquiring enzymes were abundant in the MV and VC fractions. This indicates, that P. distincta constitutively produces enzymes for phosphate uptake, which would be necessary in the phosphate-limiting environment of the Southern Ocean. On the one hand marine bacteria produce membrane extensions in order to create a larger surface in the nutrient limiting marine environment for an increased chance to get in contact to nutrients and on the other hand the results indicate an accumulation of enzymes responsible for uptake and degradation of carbohydrates and phosphates in the MV and VC. Therefore, the membrane extensions act as nutrient traps and this might be beneficial for the bacteria in the diffuse aquatic environment.
The microbial community structure and the metabolism of bacteria in the Southern Ocean are very poorly investigated. The SO is a harsh environment for all organism but nevertheless, the SO is of high importance for the climate in the world due to the high carbon dioxide uptake. In this study water samples from two different sampling sites (S1 and S2) in the SO were investigated. With a metagenomic and metaproteomic approach the key players and the metabolic activity were analyzed. Additionally, the surface water was inoculated with pectin and incubated for several days in order to analyze polysaccharide utilization loci for pectin degradation and to isolate new pectin degraders. 16S-rDNA analyses revealed the bacterial community from the genomic data. Bacteria were separated in particle-associated and free-living bacteria. The overall particle associated bacterial community at both sampling sites was comparable, with Bacteroidetes and Gammaproteobacteria as the abundant phylum. Within the Gammaproteobacteria the Alteromonadaceae and Colwelliaceae were more abundant at S2 than at S1. The free-living bacteria at S1 were dominated by the Alphaproteobacteria, especially the SAR11 clade I. Metagenomic analyses showed that both sampling sites had comparable PUL composition, but taxonomical classification of PULs was differently. The metaproteome data revealed that PUL encoded enzymes were not highly abundant. Only few CAZymes were found, mostly TonB-dependent transporters belonged to the detected PUL proteins. Taxonomical classification of proteins showed differences between the sampling sites. At S2 the genus Colwellia and Arcobacter were highly increased compared to S1. At this location Candidatus Pelagibacter, Planktomarina and Polaribacter were the abundant taxa. The functional classification at both sampling sites was comparable. The only difference was the high abundance of Epsilonproteobacteria at S2 referable to the Arcobacter species. Nevertheless, the notably taxonomical differences could not be explained by the proteomic data and the functional classification, because no specific metabolic function could be highly addressed to these bacteria. These results assumed that different abundance of the key players could be explained by different environmental conditions. The pectin enriched cultured at both sampling sites were investigated for the functional potential of pectin degrading enzymes. No metaproteomic approach could be performed due to less sampling material. Only one PUL for the degradation of rhamnogalacturonan, a component of pectin, was found at S1. In contrast, bacteria grown on pectin could be isolated from these samples. Genome sequencing of five isolates showed that functional potential of pectin degradation is available. Due to the limitations of sequence alignments, it was not possible to detect a PUL responsible for pectin utilization in the metagenomic data. The results show that the polysaccharide degradation mechanism in the Southern Ocean has to be more investigated to get knowledge about the bacterial activity in the ocean’s surface and the carbon turnover in this underexplored environment.
Summary
Outer membrane extensions are common in many marine bacteria. However, the function of these surface enlargements or extracellular compartments is poorly understood. Using a combined approach of microscopy and subproteome analyses, we therefore examined Pseudoalteromonas distincta ANT/505, an Antarctic polysaccharide degrading gamma‐proteobacterium. P. distincta produced outer membrane vesicles (MV) and vesicle chains (VC) on polysaccharide and non‐polysaccharide carbon sources during the exponential and stationary growth phase. Surface structures of carbohydrate‐grown cells were equipped with increased levels of highly substrate‐specific proteins. At the same time, proteins encoded in all other polysaccharide degradation‐related genomic regions were also detected in MV and VC samples under all growth conditions, indicating a basal expression. In addition, two alkaline phosphatases were highly abundant under non‐limiting phosphate conditions. Surface structures may thus allow rapid sensing and fast responses in nutritionally deprived environments. It may also facilitate efficient carbohydrate processing and reduce loss of substrates and enzymes by diffusion as important adaptions to the aquatic ecosystem.
Antimicrobial resistance (AMR) is of paramount importance in the context of One Health, an integrated and unifying approach that aims to achieve a sustainable balance in the well-being of people, domestic and wild animals, plants, and their shared environments. Whenever bacteria become resistant to the therapeutic effects of antibiotics, they can cause infections that are difficult to treat effectively, increasing the risk of severe disease progression and death. Although AMR can develop naturally over time and is per se “ancient”, the excessive use of antibiotics in human and veterinary medicine over the past century has significantly accelerated its emergence and spread. Opportunistic Gram-negative enterobacteria, particularly Escherichia coli (E. coli ) and Klebsiella pneumoniae (K. pneumoniae) strains, increasingly exhibit resistance to multiple classes of clinically used antibiotics, thus presenting multidrug-resistant (MDR) phenotypes. To make matters worse, some of these strains combine multidrug resistance with high-level virulence, posing a threat to both immunocompromised and healthy individuals. Consequently, MDR E. coli and K. pneumoniae have been designated as high-risk pathogens by the World Health Organization, underscoring the urgent need for new antibiotic development.
This thesis is motivated by the fact that only a limited number of international high-risk clonal E. coli and K. pneumoniae lineages stand out across all One Health dimensions and dominate the broad pool of MDR enterobacteria. While we only know little about the underlying drivers and contributing factors impacting their occurrence, emergence, and adaptation across different ecologies, this thesis employs a diverse range of bioinformatics and phenotypic approaches to identify the key factors important for the success of these lineages, also in rather under-explored settings. It includes three main components: (i) the analysis of genomic survey data of MDR E. coli isolates from ecologies in sub-Saharan Africa, (ii) the application of functional genomics and phenotyping techniques to characterize bacterial virulence and assess its clinical relevance in a food-borne E. coli strain, and (iii) the investigation of evolutionary pathways that promote the development of resistance to a novel drug combination and exploring compensatory mechanisms in a K. pneumoniae strain. To achieve these objectives, this research integrates genomics and transcriptomics with molecular biology and functional studies encompassing a comprehensive set of in vitro and in vivo virulence and resilience assays to explore MDR bacteria in-depth.
We provide compelling evidence for the broad occurrence of successful high-risk clonal lineages in the One Health context and their circulation among clinics, wildlife, and food in international locations. In the first study, we isolated extended-spectrum β-lactamase (ESBL)-producing E. coli strains from houseflies collected from various wards at the University Teaching Hospital of Butare (Rwanda). In a follow-up study, we then examined in-depth the genomes of additional ESBL-producing E. coli from the same clinic and obtained from hospitalized patients, their caregivers, associated community members, and pets. The analyses revealed that the sample sets from this sub-Saharan African context consisted predominantly of globally recognized E. coli lineages, including sequence types (ST)131, ST167, ST410, and ST617. They play a pivotal role in the further dissemination and stabilization of AMR across diverse habitats within the One Health context. Moreover, our genomic results emphasize that these One Health-related high-risk clonal lineages exhibit the ability to successfully combine multidrug resistance with high-level bacterial virulence.
To gain a more detailed understanding of the sophisticated interplay of virulence and AMR, we developed and refined a set of in vitro and in vivo methods for virulence phenotyping. These methodologies enabled us to characterize pathogens based on crucial clinical aspects such as biofilm formation, siderophore secretion, resistance to complement-mediated killing, and their capacity to cause mortality in Galleria mellonella larvae. By using a food-borne E. coli strain from an internationally recognized high-risk clonal lineage, we verified the remarkable combination of a MDR phenotype with clinically significant virulence properties, including synthesis of curli fibers and cellulose as part of biofilm formation, extensive secretion of siderophores, resilience against complement-containing human serum and pronounced mortality in the infection model.
Nevertheless, the success of One Health-related high-risk clonal lineages does not rely solely on an “ideal” synergistic interplay between bacterial virulence and AMR. It also depends on their ability to rapidly mitigate the fitness costs associated with AMR acquisition, as these costs manifest in the form of reduced competitiveness and virulence in the absence of antibiotics. However, this is at odds with the observation of the global distribution of One Health-related high-risk clonal lineages across various One Health dimensions, even in environments with expectedly low selection pressures. To comprehensively address this, we conducted experimental evolution studies selecting for ceftazidime-avibactam-resistant mutants, which illuminated the rapid adaptations to changing environments. The adaptations and compensatory mechanisms were seemingly driven by major bacterial regulators, including the envelope stress response regulator RpoE on genomic and transcriptomic levels.
In conclusion, the results of this thesis shed light on the fundamental principles that govern the character and interplay between AMR and bacterial virulence and advance our understanding of the contributors and drivers of successful MDR international high-risk clonal lineages in the One Health context. This is also important for effective and alternative intervention strategies to prospectively further address the global threat of AMR.
Highly Virulent and Multidrug-Resistant Escherichia coli Sequence Type 58 from a Sausage in Germany
(2022)
Studies have previously described the occurrence of multidrug-resistant (MDR) Escherichia coli in human and veterinary medical settings, livestock, and, to a lesser extent, in the environment and food. While they mostly analyzed foodborne E. coli regarding phenotypic and sometimes genotypic antibiotic resistance and basic phylogenetic classification, we have limited understanding of the in vitro and in vivo virulence characteristics and global phylogenetic contexts of these bacteria. Here, we investigated in-depth an E. coli strain (PBIO3502) isolated from a pork sausage in Germany in 2021. Whole-genome sequence analysis revealed sequence type (ST)58, which has an internationally emerging high-risk clonal lineage. In addition to its MDR phenotype that mostly matched the genotype, PBIO3502 demonstrated pronounced virulence features, including in vitro biofilm formation, siderophore secretion, serum resilience, and in vivo mortality in Galleria mellonella larvae. Along with the genomic analysis indicating close phylogenetic relatedness of our strain with publicly available, clinically relevant representatives of the same ST, these results suggest the zoonotic and pathogenic character of PBIO3502 with the potential to cause infection in humans and animals. Additionally, our study highlights the necessity of the One Health approach while integrating human, animal, and environmental health, as well as the role of meat products and food chains in the putative transmission of MDR pathogens.
Multi-drug resistant (MDR), gram-negative Enterobacteriaceae, such as Escherichia coli (E. coli) limit therapeutic options and increase morbidity, mortality, and treatment costs worldwide. They pose a serious burden on healthcare systems, especially in developing countries like Rwanda. Several studies have shown the effects caused by the global spread of extended-spectrum beta-lactamase (ESBL)-producing E. coli. However, limited data is available on transmission dynamics of these pathogens and the mobile elements they carry in the context of clinical and community locations in Sub-Saharan Africa. Here, we examined 120 ESBL-producing E. coli strains from patients hospitalized in the University Teaching Hospital of Butare (Rwanda), their attending caregivers as well as associated community members and livestock. Based on whole-genome analysis, the genetic diversification and phylogenetics were assessed. Moreover, the content of carried plasmids was characterized and investigated for putative transmission among strains, and for their potential role as drivers for the spread of antibiotic resistance. We show that among the 30 different sequence types (ST) detected were the pandemic clonal lineages ST131, ST648 and ST410, which combine high-level antimicrobial resistance with virulence. In addition to the frequently found resistance genes blaCTX–M–15, tet(34), and aph(6)-Id, we identified csg genes, which are required for curli fiber synthesis and thus biofilm formation. Numerous strains harbored multiple virulence-associated genes (VAGs) including pap (P fimbriae adhesion cluster), fim (type I fimbriae) and chu (Chu heme uptake system). Furthermore, we found phylogenetic relationships among strains from patients and their caregivers or related community members and animals, which indicates transmission of pathogens. Also, we demonstrated the presence and potential transfer of identical/similar ESBL-plasmids in different strains from the Rwandan setting and when compared to an external plasmid. This study highlights the circulation of clinically relevant, pathogenic ESBL-producing E. coli among patients, caregivers and the community in Rwanda. Combining antimicrobial resistance with virulence in addition to the putative exchange of mobile genetic elements among bacterial pathogens poses a significant risk around the world.
Overexpression of polo-like kinase 1 (PLK1) has been found in many different types of cancers. With its essential role in cell proliferation, PLK1 has been determined to be a broad-spectrum anti-cancer target. In this study, 3D-QSAR, molecular docking, and molecular dynamics (MD) simulations were applied on a series of novel pteridinone derivatives as PLK1 inhibitors to discover anti-cancer drug candidates. In this work, three models—CoMFA (Q² = 0.67, R² = 0.992), CoMSIA/SHE (Q² = 0.69, R² = 0.974), and CoMSIA/SEAH (Q² = 0.66, R² = 0.975)—of pteridinone derivatives were established. The three models that were established gave R²(pred) = 0.683, R²(pred) = 0.758, and R²(pred) = 0.767, respectively. Thus, the predictive abilities of the three proposed models were successfully evaluated. The relations between the different champs and activities were well-demonstrated by the contour chart of the CoMFA and CoMSIA/SEAH models. The results of molecular docking indicated that residues R136, R57, Y133, L69, L82, and Y139 were the active sites of the PLK1 protein (PDB code: 2RKU), in which the more active ligands can inhibit the enzyme of PLK1. The results of the molecular dynamic MD simulation diagram were obtained to reinforce the previous molecular docking results, which showed that both inhibitors remained stable in the active sites of the PLK1 protein (PDB code: 2RKU) for 50 ns. Finally, a check of the ADME-Tox properties of the two most active molecules showed that molecular N° 28 could represent a good drug candidate for the therapy of prostate cancer diseases.
Accelerated drug release tests are essential for quality control (QC) of long acting (non-oral) controlled release formulations. Real-time release experiments are usually required for product development, to understand the mechanism of release and to establish a correlation with in vivo release. Ideally, the accelerated test should maintain the biorelevant aspect of the in vitro method and the mechanism of release should not change under accelerated test conditions. At the same time adequate discriminatory ability is a prerequisite as the accelerated test should be able to discriminate between batches with respect to manufacturing variables that can impact on bioavailability. The objective of this thesis was to develop accelerated drug release tests for intravaginal rings (IVRs) and to gain a mechanistic understanding of the principles that facilitate in vitro drug release under accelerated test conditions. A detailed evaluation of the in vitro release characteristics of the formulations under real-time test conditions was considered as a prerequisite for developing predictive accelerated tests. Two formulations were subject of this study, in which the mechanism of release is primarily governed by drug diffusion. One formulation was the commercially available Nuvaring®, a combined hormonal contraceptive IVR that releases etonogestrel and ethinylestradiol with a constant rate over a duration of 3 weeks. The second formulation was a prototype of an investigational IVR that is supposed to be bioequivalent to the marketed formulation. The Nuvaring® provides an example of a reservoir system in which a membrane mediates diffusion, resulting in release rates that are almost constant with time, whereas the investigational IVR is a matrix-type IVR. In these devices drug release is driven by Fickian diffusion through a homogeneous matrix and decays with time. Both IVRs are based on different grades of polyethylene vinyl acetate (PEVA). Accelerated drug release tests were performed at elevated temperature and in hydro-organic solvents since these two parameters were expected to increase drug diffusion through the semicrystalline EVA copolymer. Release experiments with IVRs or endcapped segments were performed in an incubator shaker. The devices were placed in stoppered flasks containing an adequate release medium that was continuously shaken and completely replaced at predetermined time points. Release experiments with endcapped segments were also performed in a small volume version of UPS apparatus 7 (the Reciprocating Holder). Results from release experiments in these two setups were in general comparable when the release from segments was standardized to release per ring with respect to the mass ratio (segment/IVR). Real-time drug release in an aqueous release medium at a temperature of 37 °C from the Nuvaring® was slightly affected by variations in the in vitro test conditions, i.e. media volume and composition (addition of solubility enhancing agents). These variations, however, did not affect the release kinetics that continued to be zero-order with exception of the initial burst. In contrast, real-time drug release from the matrix IVR was affected by the steroid solubility in the release medium, increased with increasing media volume and reached a maximum in release media containing solubility enhancing agents, resulting in distinct release kinetics. Interestingly the steroid solubility had a distinct influence on the release rate under conditions that are commonly assumed to provide sink conditions. Even under experimental conditions that provided minimum drug solubility, the concentration of ethinylestradiol in the receptor medium never exceeded 3 % of the saturation solubility. Accelerated drug release from both IVRs could be observed after exposure to elevated temperature and/or hydro-organic release media. Overall, increased drug release in different hydro-organic media correlated with polymer swelling. The higher swelling capacity of the investigational IVR, when compared with the Nuvaring®, was accounted for a stronger degree of acceleration in different hydro-organic release media. These observations were in agreement with literature sources that report that swelling as well as diffusivity in EVA copolymers increases with increasing VA content, which is lower in the rate-controlling membrane of the Nuvaring®. For the investigational IVR a good correlation between accelerated and real-time release profiles could be obtained if changes in steroid solubility under accelerated conditions were taken into consideration. For example, a good correlation could be observed between accelerated release profiles in hydro-organic media and real-time release profiles in media containing surfactants that provide maximum drug solubility and thus eliminate boundary layer effects. This observation appears reasonable since hydro-alcoholic release media also enhance steroid solubility in the receptor compartment. In case of the Nuvaring® variations in the in vitro test parameters under real-time test conditions did not affect the release kinetics. For this IVR, the mechanism of release was maintained in hydro-organic release media and at elevated temperature. The quantitative relationship between the zero-order release constants and the test temperature could be described by the Arrhenius equation, indicating that accelerated release is governed by an increase in drug diffusion. Validation of the accelerated method with a prototype of the investigational IVR with a different drug load demonstrated that the accelerated methods were able to detect formulation changes with similar discriminatory ability as the real-time test. However, the temperature-controlled accelerated method was less sensitive to detect changes in the release characteristics of a Nuvaring® that have been induced by preliminary heat-treatment, indicating that the accelerated method may be less sensitive to detect changes in IVRs that are a result of physical aging. When the aim is to develop an accelerated method for batch release it is therefore crucial to validate the accelerated method with appropriate samples from non-conforming batches that are out of specification under real-time test conditions and have been obtained by small but deliberate variations in the critical process parameters. In both formulations the degree of acceleration could be further increased by combining the effect of hydro-organic release media with an increase in temperature. Under these test conditions the ability to differentiate between the different prototypes of the investigational IVR was maintained. Moreover, in both IVRs the mechanism of release was not affected by an additional increase in temperature when compared with release profiles in hydro-organic solvents. In conclusion, the results of this study indicate that both temperature and hydro-organic release media are valid parameters to accelerate drug release from delivery systems in which the mechanism of release is primarily governed by diffusion through dense (inert) polymer matrices (i.e. inserts, implants). A correlation between real time and accelerated release will be facilitated if drug release under real-time test conditions is independent of the test parameters. To assure the outcome of the test with respect to quality and safety it is crucial to validate the accelerated method with appropriate batches.
Background and Objectives: Alzheimer’s disease (AD) stands as a pervasive neurodegenerative ailment of global concern, necessitating a relentless pursuit of remedies. This study aims to furnish a comprehensive exposition, delving into the intricate mechanistic actions of medicinal herbs and phytochemicals. Furthermore, we assess the potential of these compounds in inhibiting human acetylcholinesterase through molecular docking, presenting encouraging avenues for AD therapeutics. Materials and Methods: Our approach entailed a systematic exploration of phytochemicals like curcumin, gedunin, quercetin, resveratrol, nobiletin, fisetin, and berberine, targeting their capability as human acetylcholinesterase (AChE) inhibitors, leveraging the PubChem database. Diverse bioinformatics techniques were harnessed to scrutinize molecular docking, ADMET (absorption, distribution, metabolism, excretion, and toxicity), and adherence to Lipinski’s rule of five. Results: Results notably underscored the substantial binding affinities of all ligands with specific amino acid residues within AChE. Remarkably, gedunin exhibited a superior binding affinity (−8.7 kcal/mol) compared to the reference standard. Conclusions: These outcomes accentuate the potential of these seven compounds as viable candidates for oral medication in AD treatment. Notably, both resveratrol and berberine demonstrated the capacity to traverse the blood-brain barrier (BBB), signaling their aptitude for central nervous system targeting. Consequently, these seven molecules are considered orally druggable, potentially surpassing the efficacy of the conventional drug, donepezil, in managing neurodegenerative disorders.
Abstract
Neutrophils are the most abundant leukocytes in circulation playing a key role in acute inflammation during microbial infections. Phagocytosis, one of the crucial defence mechanisms of neutrophils against pathogens, is amplified by chemotactic leukotriene (LT)B4, which is biosynthesized via 5‐lipoxygenase (5‐LOX). However, extensive liberation of LTB4 can be destructive by over‐intensifying the inflammatory process. While enzymatic biosynthesis of LTB4 is well characterized, less is known about molecular mechanisms that activate 5‐LOX and lead to LTB4 formation during host–pathogen interactions. Here, we investigated the ability of the common opportunistic fungal pathogen Candida albicans to induce LTB4 formation in neutrophils, and elucidated pathogen‐mediated drivers and cellular processes that activate this pathway. We revealed that C. albicans‐induced LTB4 biosynthesis requires both the morphological transition from yeast cells to hyphae and the expression of hyphae‐associated genes, as exclusively viable hyphae or yeast‐locked mutant cells expressing hyphae‐associated genes stimulated 5‐LOX by [Ca2+]i mobilization and p38 MAPK activation. LTB4 biosynthesis was orchestrated by synergistic activation of dectin‐1 and Toll‐like receptor 2, and corresponding signaling via SYK and MYD88, respectively. Conclusively, we report hyphae‐specific induction of LTB4 biosynthesis in human neutrophils. This highlights an expanding role of neutrophils during inflammatory processes in the response to C. albicans infections.
Polysaccharide is a major constituent of the total organic carbon that is generated by photosynthetic eukaryotes. In the marine realm, where approximately half of annual global carbon fixation occurs, algae can produce large amounts of polysaccharide during bloom events. Phytoplankton blooms are frequently seasonal phenomena, and spring blooms in particular have been a focus of study as they are predictable in space and time. This makes them much more amenable model systems in which to explore the processes that occur as organic carbon is recycled.
It is assumed that the bulk of the polysaccharides algae produce serve one of two primary functions - namely acting as an energy storage molecule, or they serve as structural polymers in the cell walls. Other polysaccharides may also have protective functions as exudates. Regardless of function in algae, the polysaccharides are a valuable energy source for heterotrophic bacteria. The combination of abundance and predictable or semi-predictable structure of the polysaccharides has led to proliferation of variations on a particular sequestration and degradation strategy among the Bacteroidetes and Gammaproteobacteria that is frequently characterised as being ‘selfish’. The strategy is based on uptake of poly- and especially oligosaccharides into the periplasm via the use of TonB-dependent transporters. Once in the periplasmic space, oligomers can be further degraded to monomers that can then be transported into the cytosol. This mechanism is beneficial to the cell as it needn’t then lose the nutritive benefit of the polysaccharide to other cells, which may or may not have manufactured their own degradative carbohydrate active enzymes (CAZymes).
The research articles that make up this thesis are thus based around attempts to find and elucidate the polysaccharide preferences of heterotrophic bacteria that become abundant following phytoplankton blooms.The first article is a study into the abundance of TonB-dependent transporter proteins in metaproteomes and metagenomes across a single spring phytoplankton bloom at the long term research station at Helgoland. This investigation identifies transporters for laminarin and alpha-glucans, the two most abundant glucose-based storage polysaccharides, are the most abundant predicted polysaccharide transporting TonB-dependent transporters during the bloom. However, as the bloom progressed, and particularly following a doubling of bacterial cell numbers, the proportion of predicted polysaccharide transporters dedicated to laminarin and alpha-glucan transport declined relative to transporters for less readily degraded mannose-, xylose-, and fucose-containing polysaccharides. The inference is that this change is an active response to the availability of the different polysaccharides, or their relative attractiveness as growth substrates during the period.
The second article is an in-depth look at one of the most abundant Bacteroidetes clades, which was previously unnamed, and has not to date been cultivated. The most abundant species in this clade grows rapidly and often peaks earlier than other heterotrophic clades. It was found to be limited in predicted polysaccharide consumption capability, having only PULs for predicted laminarin degradation. It is also detectable in many locations at higher latitudes where phytoplankton blooms are expected to occur, indicating this is a globally successful consumer of algal organic matter, and may have an outsize significance for global laminarin degradation given its high abundance.
The third article is a more holistic study of phytoplankton bloom associated Gammaproteobacteria, which have otherwise been rather ignored compared to the Bacteroidetes. Gammaproteobacteria overlap with Bacteroidetes to some extent in being clear consumers of laminarin, but fewer of them are clearly capable of consuming the more complex cell-wall derived polysaccharides. Some may, however, be producers of alginate, an otherwise mysteriously popular polysaccharide with Bacteroidetes, given that it is not known to be produced by bloom forming microalgae.
The fourth article then goes into detail on the PUL content of Bacteroidetes, based on metagenomic data. It finds five substrates, alpha- and beta-glucans, xylose and mannose rich polysaccharides, and alginate, are the most frequent predicted polysaccharide substrates for Bacteroidetes PULs among populations responding to the Helgoland spring blooms.
This thesis thus summarises multiple metagenomic and metaproteomic investigations into the polysaccharide consumption capabilities of marine heterotrophic bacteria. These bacteria have a profound impact on the overall carbon cycle in coastal regions, and are critical for understanding how changes in atmospheric carbon concentrations impact carbon turnover and storage in the world's oceans.
Purpose
Mixing with liquids or soft foods is a common procedure to improve acceptability of oral medicines in children but may affect drug stability and the in vivo performance of the administered drug product. The aim of the present study was to obtain an overview of the variability of critical attributes of commonly used vehicles and to identify which vehicle characteristics need to be considered when developing in vitro methods for evaluating product quality.
Methods
One product of each vehicle listed in the FDA draft guidance “Use of Liquids and/or Soft Foods as Vehicles for Drug Administration” was analyzed with regard to composition, calorific content and physicochemical properties.
Results
The studied vehicles show wide variability, both in composition and physicochemical properties. No correlation was observed between vehicle composition and physicochemical properties. Comparison of results of the present study with previously published data also provided variability in physicochemical properties within individual vehicle types.
Conclusions
To identify acceptable (qualified) vehicles for global drug product labeling, it is important that the vehicles selected for in vitro compatibility screening reflect the variability in composition and essential physicochemical properties of the vehicles recommended on the product label, rather than relying on results obtained with a single vehicle of each type. Future activities will focus on the development of standardized dosing vehicles that can represent key vehicle characteristics in all their variability to ensure reliable risk assessment.
The biological decontamination and sterilization is a crucial processing step in producing and reprocessing of medical devices. Since polymer-based materials are increasingly used for the production of medical devices, the application of conventional sterilization processes are restricted to a certain extent. Conventional sterilization techniques on the basis of high temperatures, toxic gases, or ionizing radiation can be detrimental to the functionality and performance of polymeric materials. For this reason, alternative, gentle, and efficient decontamination processes are required. One possible approach is the use of non-thermal physical plasmas. Especially atmospheric pressure plasma is receiving great interest due to the absence of vacuum systems which is highly attractive for the practical applicability. Its mechanisms of action enable the efficient killing and inactivation of micro-organisms which are attributed to the interaction of plasma-generated reactive oxygen and nitrogen species (ROS, RNS) as well as plasma-emitted (V)UV radiation. Owing to the moderate gas temperatures (near or at room temperature) so-called cold plasmas are well-suitable for the treatment of heat-sensitive materials, such as polymers, without affecting their bulk properties. The present work focuses on the investigation of atmospheric pressure plasma processes for the biological decontamination of polymers. The objective is to help elucidate on the one hand the impact of varied plasma process parameters on the inactivation of micro-organisms and on the other hand the influence of plasma on the surface properties of the substrate. The investigations were performed by means of a high-frequency driven plasma jet (from the product line kINPen) operated with argon and argon-oxygen mixtures. Three main aspects were analyzed: 1. The effect of plasma on the viability of micro-organisms dependent on working gas, treatment time, and the sample distance (distance between the jet nozzle and the substrate). 2. The plasma-based removal of microbial biofilms. 3. The effects of the plasma treatment on the surface properties of selected polymers. Additionally to the capability of the applied plasma jet in killing microbes the efficacy of this plasma jet for the removal of complex biological systems (e.g. biofilms) is shown. To model cell constituents of bacteria different synthetic polymers were chosen to gain insight into the decomposition process responsible for biofilm degradation. By investigating the impact of atmospheric pressure plasma on physico-chemical surface properties of various synthetic aliphatic and aromatic polymers the interaction mechanisms between plasma and plasma-exposed material are discussed. These studies are accompanied by applying different optical plasma diagnostic techniques (optical emission spectroscopy and two-photon absorption laser induced fluorescence spectroscopy) to obtain information on the plasma gas phase which contributes to the elucidation of the reaction mechanisms occurring during plasma exposure. Moreover, it is presented to which extent the plasma treatment influences the surface properties of polymers during the plasma-based bio-decontamination process and further, the benefits of surface-functionalized polymers for biomedical application is discussed.
Species of the genus Drosera, known for carnivorous plants, such as sundew, have been traditionally used for centuries as medicinal plants. Efficacy-determining compounds are naphthoquinones and flavonoids. Flavonoids possess a broad spectrum of bioactive properties, including biofilm inhibitory activity. Biofilms render antibiotics ineffective, contributing to the current rise in antimicrobial resistance. In this study, the biofilm inhibitory activity of two European sundew species (Drosera rotundifolia and Drosera intermedia) grown agriculturally in Germany and four commercial sundew products (declared as Drosera longifolia, Drosera sp. and Drosera planta trit.) against three multidrug-resistant Escherichia coli strains was tested. The aim of the study was to comparatively investigate the biofilm inhibitory potential of sundew species extracts grown locally in northern Germany and commercial sundew products. The minimum biofilm inhibitory concentration of the European sundew species was approx. 35 µg mL−1. In comparison, commercial sundew products ranged in concentration from 75 to 140 µg mL−1. Additionally, individual compounds isolated from European sundew were tested. Among these compounds, biofilm inhibitory activity was determined for four of the eight substances, with 2″-O-galloyl hyperoside standing out for its activity (38 µg mL−1). The whole plant extracts of Drosera rotundifolia and Drosera intermedia proved to be more effective than the commercial products and the single compounds in its biofilm inhibition activity against Escherichia coli strains. Sundew extracts may serve as a potential therapeutic approach for targeting biofilm production.
Crab Spa, is a stable diffuse-flow hydrothermal vent site located at the 9°N hydrothermal vent field on the East Pacific Rise (EPR). Remarkably, the physicochemical conditions at Crab Spa have remained largely constant since its discovery in 2007 providing a uniquely stable environment in which a well-adapted and stable microbial community has evolved. This microbial community is dominated by the class Campylobacteria, accounting for up to 90% of the community. Little is known, however, about the metabolic pathways that allow the Campylobacteria to dominate the bacterial community at Crab Spa. To address this fundamental question, a two-pronged approach was taken consisting of first determining the dominant metabolic pathways in situ, and second to study those same metabolic pathways and their controls in more detail under defined conditions in vitro in the model campylobacterium Sulfurimonas denitrificans.
Metagenomic analysis of two environmental samples provided the blueprint to determine the metaproteomic profile of the Crab Spa microbial community. This allowed to identify the dominant organisms and their major metabolic pathways sustaining the microbial community at Crab Spa. About 90% of the genes for transcription and protein synthesis of the metagenome sequences belonged to just three genera of Campylobacteria: Sulfurimonas, Sulfurovum and Arcobacter. The metaproteomic analyses confirmed that the active microbial community was dominated by Campylobacteria, carrying out carbon fixation via the reductive TCA cycle predominantly fueled by the oxidation of sulfide and sulfur with nitrate and oxygen. The analysis further revealed that pathways might be partioned between different members of the bacterial community. Proteins involved in electron acceptor–related pathways, in particular denitrification, accounted for up to 20% of the whole metaproteome, which could be seen as an adaptation to the scarcity of electron acceptors at Crab Spa. Conversely, proteins related to electron donor–associated metabolic pathways accounted for less than 0.1% of the metaproteome, possibly in response to the high concentration of the electron donor. To follow up on this hypothesis, chemostat experiments with S. denitrificans were performed under either electron-acceptor or -donor limitation. These experiments confirmed that electron-acceptor limitation lead to the elevated expression of electron-acceptor proteins. However, a higher expression of electron-donor proteins was not observed under electron-donor limitation. Besides hydrogen sulfide, elemental sulfur has the potential to serve as an important electron donor at Crab Spa. However, up to know no information was available on how Campylobacteria might be able to utilize elemental sulfur. For this, S. denitrificans grew with either thiosulfate or cyclooctasulfur (S8) as sole electron donors and its transcriptome and proteome was compared. The results revealed a differential expression of the SOX sulfur oxidation pathway (soxCDYZ and soxABXYZ) in response to the two different sulfur compounds. Based on these findings, a model for the oxidation of cylcooctasulfur was proposed that also applies to other sulfur-oxidizing Campylobacteria and helps in the interpretation of environmental metatranscriptomic and –proteomic data (Götz, Pjevac, et al., 2018; Lahme et al., 2020). The presented results help to better understand the microbial processes at hydrothermal vents.
Despite recent advances in the treatment of non-small cell lung cancer (NSCLC), acquired drug resistance to targeted therapy remains a major obstacle. Epithelial-mesenchymal transition (EMT) has been identified as a key resistance mechanism in NSCLC. Here, we investigated the mechanistic role of key EMT-regulating small non-coding microRNAs (miRNAs) in sublines of the NSCLC cell line HCC4006 adapted to afatinib, erlotinib, gefitinib, or osimertinib. The most differentially expressed miRNAs derived from extracellular vesicles were associated with EMT, and their predicted target ZEB1 was significantly overexpressed in all resistant cell lines. Transfection of a miR-205-5p mimic partially reversed EMT by inhibiting ZEB1, restoring CDH1 expression, and inhibiting migration in erlotinib-resistant cells. Gene expression of EMT-markers, transcription factors, and miRNAs were correlated during stepwise osimertinib adaptation of HCC4006 cells. Temporally relieving cells of osimertinib reversed transition trends, suggesting that the implementation of treatment pauses could provide prolonged benefits for patients. Our results provide new insights into the contribution of miRNAs to drug-resistant NSCLC harboring EGFR-activating mutations and highlight their role as potential biomarkers and therapeutic targets.
Abstract
Because isoenzymes of the experimentally and therapeutically extremely relevant sirtuin family show high similarity, addressing the unique selectivity pocket of sirtuin 2 is a promising strategy towards selective inhibitors. An unrelated approach towards selective inhibition of isoenzymes with varied tissue distribution is targeted drug delivery or spatiotemporal activation by photochemical activation. Azologization of two nicotinamide‐mimicking lead structures was undertaken to combine both approaches and yielded a set of 33 azobenzenes and azopyridines that have been evaluated for their photochemical behaviour and bioactivity. For some compounds, inhibitory activity reached the sub‐micromolar range in their thermodynamically favoured E form and could be decreased by photoisomerization to the metastable Z form. Besides, derivatization with long‐chain fatty acids yielded potent sirtuin 2 inhibitors, featuring another intriguing aspect of azo‐based photoswitches. In these compounds, switching to the Z isomer increased aqueous solubility and thereby enhanced biological activity by up to a factor of 21. The biological activity of two compounds was confirmed by hyperacetylation of sirtuin specific histone proteins in a cell‐based activity assay.