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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.
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.
Symbiotic interactions are a key element of biological systems. One powerful strategy to gain insight into these interactions, and into biological systems in general, is the analysis of proteins expressed in situ using metaproteomics. In this thesis, host-microbe interactions in two mutualistic associations between chemosynthetic sulfur-oxidizing endosymbionts and marine invertebrates, the deep-sea tubeworm Riftia pachyptila and the shallow-water clam Codakia orbicularis, were studied by adapted and optimized metaproteomics methods.
The Riftia symbiosis, which inhabits hydrothermal vents in the deep sea, and in which the host completely depends on its symbiont for nutrition, has fascinated researchers for about four decades. Yet, the interaction mechanisms between both partners have been understudied so far. Additionally, while different aspects of the host’s biology have been described, a comprehensive analysis has been lacking. Moreover, although only one symbiont 16S rRNA phylotype is present in Riftia, the symbiont population of the same host expresses proteins of various redundant or opposed metabolic pathways at the same time. As the symbionts also exhibit a wide variety in size and shape, symbionts of different size might have dissimilar physiological functions, which remained as of now to be elucidated. In this thesis, we addressed both, the host-symbiont interaction mechanisms, and physiological roles of symbiont subpopulations. A comprehensive Riftia host and symbiont protein database was generated as prerequisite for metaproteomics studies by de novo sequencing the host’s transcriptome and combining it with existing symbiont protein databases. This database was then used for metaproteomics comparisons of symbiont-containing and symbiont-free Riftia tissues, to gain insights into host-symbiont interactions on the protein level. The impact of energy availability on host-symbiont interactions was studied by comparing specimens with stored sulfur (i.e., high energy availability) with specimens in which sulfur storages were depleted. We employed optimized liquid chromatography peptide separation to increase metaproteome coverage. With this analysis, we identified proteins and mechanisms likely involved in maintaining the symbiosis, under varying environmental conditions. We unraveled key interaction mechanisms, i.e.: (i) the host likely digests its symbionts using abundant digestive enzymes, and, at the same time, (ii) a considerable part of the worm’s proteome is involved in creating stable internal conditions, thus maintaining the symbiont population. Furthermore, (iii) the symbionts probably employ eukaryote-like proteins to communicate with the host. (iv) Under conditions of restricted energy availability, the host apparently increases digestion pressure on the symbiotic population to sustain itself.
Riftia symbionts of different size apparently have dissimilar metabolic roles, as revealed in this thesis. We enriched symbionts of different sizes using gradient centrifugation. These enrichments were subjected to protein extraction using a protocol optimized for the small sample amount available. Metaproteomics analysis included a gel-based workflow and evaluation of the complex dataset with machine learning techniques. Based on our metaproteomics study, we propose that Riftia symbionts of different cell size correspond to dissimilar physiological differentiation stages. Smaller cells are apparently engaged in cell differentiation and host interactions. Larger cells, on the other hand, seem to be more involved in synthesis of various organic compounds. Supposedly, in large symbionts endoreduplication cycles lead to polyploidy. Our results indicate that the Riftia symbiont employs a large part of its metabolic repertoire at the same time in the stable host environment.
The symbiont of the shallow-water clam Codakia orbicularis, which, like the Riftia symbiont, relies on reduced sulfur compounds as energy source and fixes inorganic carbon, is, unexpectedly, also able to fix atmospheric nitrogen, as shown by metaproteomic, genomic and biochemical analysis. Potentially, this benefits the host, as Codakia digests its symbiont and might thus supplement its diet with organic nitrogen fixed by the symbionts in addition to organic carbon in its nitrogen-poor seagrass habitat.
Research on the science and the fiction of supercritical fluid chromatography (SFC) has been ongoing for more than five decades. Today, packed column SFC promises speedy solutions to chiral and semi-preparative separation problems, but academia has been reluctant to incorporate SFC into its curriculum, as doubts linger concerning its practicability. This work sought to explore the merits of SFC in hyphenation with electrospray ionization--single quadrupole mass spectrometry (ESI-MS) and supercritical fluid extraction (SFE) in various aspects of medicinal chemistry and bioanalysis within an academic setting.
SFC was investigated for its usefulness in assessing the purity and the stability of synthesis products, and the quantification of chiral and achiral metabolites - domains conventionally occupied by high performance liquid chromatography (HPLC).
Confronted with analytes prone to hydrolysis (cyclic polysulfides) and UV-induced configurational changes (aza-stilbenes), fast elution by water-free SFC-MS proved complementary to traditional chromatographic techniques.
The quantification of antidepressant ketamine metabolites presented an opportunity to assess supercritical fluid techniques within a bioanalytical context. While SFC hyphenated to single quadrupole MS did not reach the sensitivity levels of HPLC coupled to triple quadrupole MS/MS, exploitation of supercritical CO2 reduced analysis times more than six-fold (60 minutes by HPLC vs 10 minutes by SFC). When coopted for both extraction and analysis, SFE-SFC-MS simplified sample preparation and promoted the transition from off- to on-line bioanalysis. Similar results were obtained when SFC was applied to acidic and basic metabolites of the controversial anodyne flupirtine. Again, SFC featured shorter run times but also expanded the target metabolite spectrum covered within one run.
Finally, a tiered approach to validation demonstrated the reliability achievable by SFC. Critical applications such as quantification of the newly approved antidepressant ketamine or the recently withdrawn analgesic flupirtine were comprehensively validated according to guidelines on bioanalytical method validation by the European Medicines Agency. Notably, this included the first fully validated chromatographic methods for the putative antidepressant (2R,6R)-6-hydroxynorketamine, and the first report of EMA-conforming quantification by on-line SFE-SFC-MS from urine.
Separation scientists find themselves confronted with diverse problems and tools. Although parsing only a microscopic subsection of the available chemical and analytical space, the results obtained here suggest SFC to be a fast and versatile addition to conventional chromatographic methods employed at the intersection of medicinal chemistry and bioanalysis.
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.
Background
In addition to the broad dissemination of pathogenic extended-spectrum beta-lactamase (ESBL)-producing Escherichia (E.) coli in human and veterinary medicine and the community, their occurrence in wildlife and the environment is a growing concern. Wild birds in particular often carry clinically relevant ESBL-producing E. coli.
Objectives
We analyzed ESBL-producing and non-ESBL-producing E. coli obtained from wild birds in Mongolia to identify phylogenetic and functional characteristics that would explain the predominance of a particular E. coli clonal lineage in this area.
Methods
We investigated ESBL-producing E. coli using whole-genome sequencing and phylogenetics to describe the population structure, resistance and virulence features and performed phenotypic experiments like biofilm formation and adhesion to epithelial cells. We compared the phenotypic characteristics to non-ESBL-producing E. coli from the same background (Mongolian wild birds) and genomic results to publicly available genomes.
Results and Conclusion
We found ESBL-producing E. coli sequence type (ST) 1159 among wild birds in Mongolia. This clonal lineage carried virulence features typical for extra-intestinal pathogenic or enterotoxigenic E. coli. Comparative functional experiments suggested no burden of resistance in the ST1159 isolates, which is despite their carriage of ESBL-plasmids. Wild birds will likely disseminate these antibiotic-resistant pathogens further during migration.
Multidrug-resistant gram-negative (MRGN) bacteria are a serious threat to global health. We used genomics tostudy MRGN obtained from houseflies in a tertiary Rwandan hospital. Our analysis revealed a high abundance ofdifferent MRGN includingE. colipathogenic lineage ST131 suggesting the important role of flies in disseminatinghighly virulent pathogens in clinical settings and beyond