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Pentathiepins are cyclic polysulfides that exert antiproliferative and cytotoxic activity in cancer cells, induce oxidative stress and apoptosis, and potently inhibit GPx1. These properties render this class of compounds promising candidates for the development of anticancer drugs. However, the biological effects and how they intertwine to promote high cytotoxicity have not been systematically assessed throughout a panel of cancer cell lines from distinct tissues of origin. In this thesis, six novel pentathiepins were analyzed and constitute the second generation of compounds with additional properties such as fluorescence or improved water solubility to facilitate cellular testing. All compounds underwent extensive biological evaluation in 14 human cancer cell lines. These studies included investigations of the inhibitory potential with regards to GPx1 and cell proliferation, examined the cytotoxicity in human cancer cell lines, as well as the induction of oxidative stress and DNA strand breaks. Furthermore, selected hallmarks of apoptosis, ferroptosis, and autophagy were studied. Experimental approaches regarding these cellular mechanisms included observing morphological changes, detecting phosphatidyl serine exposure and caspase activity, and quantifying cleaved PARP1 and levels of LC3B II. In addition, the analysis of the cell cycle aimed to identify aberrations or arrests in cell division.
Five of the six tested pentathiepins proved to be potent inhibitors of the GPx1, while all six exerted high cytotoxic and antiproliferative activity, although to different extents. There was a clear connection observed between the potential to provoke oxidative stress and damage to DNA in the form of single- and double-strand breaks both extra- and intracellularly. Furthermore, various experiments supported apoptosis but not ferroptosis as the mechanism of cell death in four different cell lines. In particular, the externalization of PS, the detection of activated caspases, and the cleavage of PARP1 corroborated this conclusion. Additionally, indications for autophagy were found, but more investigations are required to verify the current data. The findings of this dissertation are mainly in line with the postulated mechanism of action proposed for pentathiepins and a previous publication from our group that described their biological activity. However, the influence of modulators such as oxygen and GSH on the biological effects was ambiguous and dependent on the compound. The expression profile of the cell lines concerning GPx1 and CAT did not influence the cellular response toward the treatment, whereas the cell doubling time correlated with the cytotoxicity.
As the various pentathiepins give rise to different biological responses, modulation of the biological effects depends on the distinct chemical structures fused to the sulfur ring. This may allow for future optimization of the anticancer activity of pentathiepins. An analysis of the structure-activity relationships revealed that the piperazine scaffold was associated with superior biological activity compared to the pyrrolo-pyrazine backbone. Furthermore, substituents with electron-withdrawing properties or those providing a free electron pair, such as fluorine or morpholine, were advantageous. These findings should help design and synthesize the next generation of pentathiepins, thereby expanding the library of compounds, allowing for the further deduction of structure-activity relationships and an improved understanding of their mechanism of action.
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.
In the search for bioactive compounds, 32 fungal strains were isolated from Indonesian marine habitats. Ethyl acetate extracts of their culture broth were tested for cytotoxic activity against a urinary bladder carcinoma cell line and for antifungal and antibacterial activities against fish and human pathogenic bacteria as well as against plant and human pathogenic fungi. Bioassay-guided fractionation led to the isolation of bioactive compounds. Altogether 14 compounds were isolated and further elucidated. The compounds were obtained from the ethyl acetate and dichloromethane extracts of six fungal strains. They included 9 polyketides, 2 terpenes, 1 alkaloid and 2 till now undefined structures.
Heparin is an anticoagulant drug. It is important in the treatment of deep vein thrombosis,pulmonary embolism and during surgeries. Heparin-induced thrombocytopenia (HIT) is a severe adverse reaction caused by the formation of ultralarge complexes of platelet factor 4 (PF4) with unfractionated heparin (UFH). It can lead to limb loss or fatal events like stroke, myocardial infarction or pulmonary embolism. HIT has an incidence of about 3% in patients receiving anticoagulative heparin treatment. PF4 is a tetrameric protein, released from the α-granules of platelets upon activation. PF4 is known to form antigenic complexes with UFH accompanied by structural changes of PF4. In this thesis, the size and size distribution of PF4 and PF4/heparin complexes were analyzed using asymmetrical flow field-flow-fractionation (AF4), photon correlation spectroscopy (PCS) and atomic force microscopy (AFM). PF4 tends to form auto-aggregates and to adsorb to different surfaces, including regenerated cellulose, polyethersulfone, quartz and glass. The aggregates are less pronounced in solutions at isotonic NaCl concentration. Arginine and Tween 20 were identified as possible ingredients to hinder the auto-aggregation of PF4. Also, it is shown by combining circular dichroism (CD) spectroscopy, atomic force microscopy (AFM) and isothermal titration calorimetry (ITC) with UFH and defined chain length (16-, 8-, 6-, 5-mer) heparins that structural changes (i.e., increase in β-sheets) alone are not sufficient to induce antigenicity. While UFH, 16-, 8-, and 6-mer heparins all induced an increase in the antiparallel β-sheet content to > 30% (as determined by CD spectroscopy), complex antigenicity as measured by anti-PF4/heparin antibody binding in an enzyme-linked immunosorbent assay (EIA) was only induced by UFH and 16-mer heparin. Fondaparinux (5-mer heparin), which forms in vitro non-antigenic complexes with PF4, did not induce structural changes of PF4. Interestingly, the structural changes induced by antigenic UFH and 16-mer heparin but not by non-antigenic shorter heparins were reversible at higher heparin concentrations. Furthermore, the complexes formed by PF4 with longer heparins were larger than those formed with shorter heparins as shown by atomic force microscopy (AFM). UFH, HO16 and HO08 are able to form ultralarge multimolecular complexes with PF4. ITC data indicated strong electrostatic interactions and energetically unfavorable conformational changes of PF4 with longer heparins, while for the short heparins, favorable conformational changes in the structure of PF4 are induced. This explains the reversibility of the structural changes seen for UFH and HO16 upon addition of an over-saturating amount of heparin. Finally, using differential scanning calorimetry (DSC) the thermal stability of PF4 and PF4/heparin complexes was assessed. Despite its tendency to form auto-aggregates, PF4 is a heat-stable protein. This stability is, length dependently, even increased in complex with heparins. This work shows important differences in the binding between PF4 and heparins of different chain length and might be relevant for the understanding of other biological functions of heparins (e.g., involvement in allergic and inflammatory reactions).
The biodiversity of marine microorganisms opens a promising potential for the discovery of new technical enzymes. During this study a characterization of marine microorganisms, isolated from Arctic or Antarctic ice, sea water or sediment from the ocean was performed based on a comprehensive strain collection at the Alfred-Wegener-Institut für Polar- und Meeresforschung. These marine psychrophilic bacteria indicated a wide spectrum of extracellular cold-active enzymes. 16S rRNA sequencing revealed that many of these psychrophilic bacteria represent new species. Characterization of selected isolates by means of transmission electron or raster electron microscopy showed remarkably pleomorphic cellular structures throughout their growth. The major part of this thesis focuses on a marine Antarctic, psychrophilic bacterium (strain ANT/505) isolated from sea ice covered surface water from the Southern Ocean, which was identified to express a very uncommon enzymatic activity for the marine environment, namely a pectinolytic activity. The sequencing of the 16S rRNA of isolate ANT/505 and biochemical tests indicated a taxonomical affiliation to the specie Pseudoalteromonas haloplanktis. The supernatant of this bacterial isolate showed after growth on citrus pectin three different pectinolytic activities. By activity screening of a genomic DNA library of isolate ANT/505 in Escherichia coli, two different pectinolytic clones could be isolated. Subcloning and sequencing revealed two open reading frames of 1671 and 1968 nt corresponding to proteins of 68 and 75 kDa. The deduced amino acid sequence of the two orfs showed homology to pectate lyases from Erwinia chrysanthemi and Aspergillus nidulans. The pectate lyases contain signal peptides of 17 and 26 amino acids length that were correctly processed after overexpression in E. coli BL21. Both enzymes were purified by anionic exchange chromatography. Maximal enzymatic activities for both pectate lyases were observed at a temperature of 30°C and a pH range of 9-10. The Km values of both lyases for pectate and citrus pectin were 1 g⋅l-1 and 5 g⋅l-1, respectively. Calcium was required for activity on pectic substrates, while the addition of 1 mM ethylenediaminetetraacetic acid (EDTA) resulted in complete inhibition of the enzymes. These two cold-adapted enzymes represent the first pectate lyases isolated and characterized from a marine bacterium. Further cloning and sequence analyses revealed that PelA from P. haloplanktis is an exceptionally big bifunctional enzyme featuring pectate lyase and pectin methylesterase activity. The deduced amino acid sequence of the pectin methylesterase domain showed homology to group I pectin methylesterases from Erwinia chrysanthemi and Erwinia carotovora. The pectin methylesterase domain of PelA was found to show highest homology to a potential pectin methylesterase from Saccharophagus degradans strain MD2-40. Maximum pectin methylesterase activity of PelA was detected at a pH of 7.5 and a maximum temperature of 30°C. This cold-adapted enzyme revealed high remaining pectin methylesterase activity at low temperatures around 5°C and was quickly unstabilized at temperatures above 45°C. The analysis of the localization of the two pectinolytic genes on the genome of P. haloplanktis ANT/505 revelaed that these pectinase genes are expressed from independent cistrons, which are not clustered but located at distant positions on chromosome I of the P. haloplanktis genome. It was found that the transcription of both pectinase genes is induced by the presence of pectin. By means of primer extension the promoter regions of both cistrons were detected.
Summary Cyanobacteria are a diverse and ancient group of photosynthetic prokaryotic organisms that can inhabit a wide range of environments including extreme conditions such as hot springs, desert soils and the Antarctic. They are abundant producers of natural products well recognized for their bioactivity and utility in drug discovery and biotechnology applications. Novel intracellular and extracellular compounds from various cultured and field cyanobacteria with diverse biological activities and a wide range of chemical classes have considerable potential for development of pharmaceuticals and other biomedical applications. However, cyanobacteria are still viewed as unexplored source of potential drugs. Especially the collections of cyanobacterial strains from South East Asia where biodiversity is high are still largely unexplored. Thus, we investigated twelve soil cyanobacterial strains isolated from soil samples collected from rice, cotton, and coffee fields in Dak Lak province of Vietnam and one marine strain, Lyngbya majuscula collected from Khanh Hoa province of Vietnam for the search for new compounds with antimicrobial and cytotoxic activities. From the 12 soil cyanobacterial strains, 48 extracts prepared with n-hexane, methanol, and water for biomasses and ethyl acetate for growth media were screened for antibacterial activity against Gram-positive bacteria (Bacillus subtilis ATCC 6051 and Staphylococcus aureus ATCC 6538) and Gram-negative bacteria (Escherichia coli ATCC 11229, Pseudomonas aeruginosa ATCC 27853). Of 48 extracts, 47.92% and 45.83% showed activity against Bacillus subtilis and Staphylococcus aureus, respectively, while 22.92% and 6.25% exhibited activity against Escherichia coli and Pseudomonas aeruginosa, respectively. All investigated cyanobacteria (12/12) showed antibacterial activity to at least one of the test organisms applied. Among the active extracts, extracts obtained from 5 cyanobacterial strains, Westiellopsis sp. VN, Calothrix javanica, Scytonema ocellatum, Anabaena sp. and Nostoc sp. showed the highest strength and range of antibacterial activity and therefore were selected for chemical investigation with an emphasis on the isolation and structure elucidation of antimicrobial compounds. Bioassay-guided fractionation of the methanol extract prepared from biomass of Westiellopsis sp. VN by silica gel chromatography, followed by sephadex LH-20 chromatography and reversed-phase HPLC led to isolation and identification of 6 compounds as ambiguine D isonitrile, ambiguine B isonitrile, dechloro-ambiguine B isonitrile, fischerellin A, hydroxy-eicosatetraenoic acid and methoxy-nonadecadienoic acid. Identification of these active compounds was established by direct comparison of our spectroscopic data, including 1H NMR and HR-ESI-MS with those reported in the literature. All these compounds showed biological activity. The identification of fatty acids and other volatile components by GS-MS in the active MeOH fraction obtained from EtOAc extract of growth medium was done before commencing further fractionation processes. Culture optimization of Westiellopsis sp.VN showed that NaNO3 deficiency increased accumulation of antimicrobial compounds. Biosynthesis of antimicrobial compounds increased over cultivation time resulting in increased diameter of inhibition zone of the methanol extract towards the end of the 7-to 8- week growth period, but the most clear inhibition zone of this extract was detected after cultivation time of 8 weeks. Bioassay-guided fractionation of the methanol extract prepared from biomass of either Calothrix javanica by C18 chromatography followed by reversed-phase HPLC or Scytonema ocellatum by C18 chromatography followed by silica gel chromatography and reversed-phase HPLC led to isolation and structure elucidation of new cyclic peptide named daklakapeptin. Structure of daklakapeptin was elucidated by exhaustive 1D (1H) and 2D (COSY, TOCSY, NOESY, HMQC, HMBC) NMR spectroscopy in combination with HR-ESI-MS. Daklakapeptin was found to have totally 12 residues including 6 proteinogenic amino acids (Pro, Tyr, Ile, Leu, Gln, Thr), 4 complexes (X,Y,T,Z) and the methyl derivative of Ile. The exact sequence of daklakapeptin is shown in following figure with X: (CH3)2CHCH2CH2CH(NH-)CH2CO-, Y:(CH3)2CHCH(OH)CH(NH-)CO-, T: HOCH2CH2CH(NH-)CO-, Z: HOCH2CHOHCH(NH-)CO- This new cyclic peptide exhibited antibacterial activity against Staphylococcus aureus with diameter of inhibition zone of 12.5 mm in concentration of 200 mg/disc. Further test for activity to other bacteria and for cytotoxic activity are in progress. Using reversed-phase HPLC to separate compounds in the crude ethyl acetate extract obtained from culture medium of Anabaena sp. led to isolation and structure elucidation of flourensadiol. The structure of flourensadiol was established using an extensive array of 1D (1H, 13C, DEPT-135) and 2D (HMQC, COSY, HMBC) NMR and HR-ESI-MS experiments. Flourensadiol was isolated previously from the common western shrub Flourensia cernua. However, only MS, IR, and proton NMR data but no reports on biological activity were available. In this study, we report the complete NMR data of flourensadiol for the first time. Flourensadiol was found to be very strong antibacterial active against Escherichia coli with diameter of inhibition zone of 20.0 mm in concentration of 200 mg/disc. Further test for activity to other bacteria and cytotoxic activity are in progress. Bioassay-guided fractionation of the methanol extract from biomass of Nostoc sp. by silica gel chromatography followed by C18 chromatography and reversed phase HPLC led to isolation of the active fraction NsF2 which exhibited antibacterial activity against Staphylococcus aureus with diameter of inhibition zone of 10.0 mm in concentration of 500 mg/disc. The low resolution ESI-MS of fraction NsF2 showed signal at m/z 426 [M+H]+. The NMR and MS characterization of compounds in fraction NsF2 is in progress. Bioassay-guided fractionation of the methanol extract prepared from biomass of marine cyanobacterium Lyngbya majuscula collected from Khanh Hoa province of Vietnam by various chromatographic methods (CC, PTLC, HPLC) afforded 3 cytotoxic compounds anhydrodebromoaplysiatoxin, debromoaplysiatoxin, and anhydroaplysiatoxin. Identification of these cytotoxic compounds was established by direct comparison of our spectroscopic data, including (1H, 13C) NMR and HR-ESI-MS with those reported in the literature. In our study, debromoaplysiatoxin and anhydroaplysiatoxin exhibited cytotoxic activity against bladder cancer cell line 5637 with IC50 of 86 ng/ml and 40 ng/ml, respectively but anhydrodebromoaplysiatoxin was not yet tested for cytotoxic activity. The identification of fatty acids by GS-MS technique in the n-hexane extract obtained from biomass of this marine cyanobacterium was undertaken before commencing further fractionation processes. The presented results prove that soil cyanobacteria are a promising source to yield chemical and pharmaceutical interesting compounds.
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.
Chemistry and biology of Phenolics isolated from Myricaria germanica (L.) Desv. (Tamaricaceae)
(2014)
In accordance with the recent worldwide interest in plant phenolics, which emerges from their broad range of biological activities, particular emphasis has been focused, in the present thesis, on the constitutive phenolics of the extract of Myricaria germanica (L.) Desv. (Tamaricaceae). During the current thesis twenty phenolics (1 – 20) were isolated and identified from the aqueous/ethanol extract of the whole Myricaria germanica plant. The isolates include four hitherto unknown natural phenolics (2, 10, 12 and 20). Also, the cytotoxic activities of M. germanica extract, column fractions, and one new natural isolate against three different solid tumor cell lines, namely, breast cancer (MCF-7), prostate (PC-3), and liver (Huh-7) cancer cell using SRB viability assay have been investigated and first insights into mode of action have been obtained.
Chemosymbiosis in marine bivalves – unravelling host-symbiont interactions and symbiotic adaptions
(2018)
Symbiosis essentially forms the cornerstone of complex life on earth. Spearheading
symbiosis research in the last few decades include the exploration of diverse mutualistic
animal-bacterial associations from marine habitats. Yet, many facets of symbiotic
associations remain under-examined. Here we investigated marine bivalves of the genera
Bathymodiolus and Codakia, inhabiting hydrothermal vents and shallow water
ecosystems, respectively, and their bacterial symbionts. The symbionts reside
intracellularly within gill epithelia and supply their host with chemoautotrophically fixed
carbon. They oxidize reduced substrates like sulfide (thiotrophic symbionts) and methane
(methanotrophic symbionts) from surrounding fluids for energy generation. The nature of
interactions between host and symbiont at the metabolic and physical level, as well as
between the holobiont and its environment remain poorly understood. In vitro cultivations
of both symbiont and host are difficult till date, hampering the feasibility of targeted
molecular investigations.
We bypassed culture-based experiments by proteogenomically investigating physically
separated fractions of host and symbiont cell components for the bivalves Bathymodiolus
azoricus, Bathymodiolus thermophilus and Codakia orbicularis. Using these
enrichments, we sequenced the symbionts’ genomes and established semi-quantitative
host-symbiont (meta-) proteomic profiles. This combined approach enabled us to resolve
symbiosis-relevant metabolic pathways and adaptations, detect molecular factors
mediating physical interactions amongst partners and to understand the association of
symbiotic traits with the environmental factors prevailing within habitats of the respective
bivalve.
Our results revealed intricate metabolic interdependence between the symbiotic partners.
In Bathymodiolus, these metabolic interactions included (1) the concentration of essential
substrates like CO2 and thiosulfate by the host for the thiotrophic symbiont, and (2) the
host’s replenishment of essential TCA cycle intermediates for the thiotroph that lacks
biosynthetic enzymes for these metabolites. In exchange (3), the thiotroph compensates
the host’s putative deficiency in amino acid and cofactor biosynthesis by cycling aminoacids
derived from imported precursors back to the host. In case of Codakia orbicularis,
the symbionts may metabolically supplement their host with N-compounds derived from
fixation of molecular nitrogen, a trait that was hitherto unknown in chemosynthetic
thiotrophic symbionts.
Individual proteogenomic investigations of the bivalves Bathymodiolus azoricus and
Bathymodiolus thermophilus showed that their symbionts are able to exploit a multitude
of energy sources like sulfide, thiosulfate, methane and hydrogen to fuel chemosynthesis.
The bivalves and their thiotrophic symbionts, however, are particularly adapted to
thiosulfate-utilization, as indicated by mitochondrial production and concentration of
thiosulfate by host and dominant expression of thiosulfate oxidation enzymes in the
symbiont. This may be advantageous, because thiosulfate is less toxic to the host than
sulfide. The central metabolic pathways for energy generation, carbon and nitrogen
assimilation and amino acid biosynthesis in thiotrophic symbionts of both Bathymodiolus
host species are highly conserved. Expression levels of these pathways do, however, vary
between symbionts of both species, indicating differential regulation of enzyme synthesis,
possibly to accommodate differences in host morphology and environmental factors.
Systematic comparison of symbiont-containing and symbiont-free sample types within
and between B. azoricus and B. thermophilus revealed the presence of ‘symbiosisspecific’
features allowing direct host-symbiont physical interactions. Host proteins
engaged in symbiosis-specific functions include 1) a large repertoire of host digestive
enzymes predominant in the gill, possibly facilitating symbiont population control and
carbon acquisition via direct enzymatic digestion of symbiont cells and 2) a set of host
pattern-recognition receptors, which may enable the host to selectively recognize
pathogens or even symbionts “ripe” for consumption. Symbiont proteins engaged in
symbiosis-specific interactions included 3) an enormous set of adhesins and toxins,
putatively involved in symbiont colonization, persistence and host-feeding.
Bathymodiolus symbionts also possess repertoires of CRISPR-Cas and restrictionmodification
genes for phage defense that are unusually large for intracellular symbionts.
Genomic and proteomic comparisons of thiotrophic symbionts of distinct Bathymodiolus
host species from different vent sites revealed a conserved core genome but divergent
accessory genomes. The B. thermophilus thiotroph’s accessory genome was notably more
enriched in genes encoding adhesins, toxins and phage defense proteins than that of other
Bathymodiolus symbionts. Phylogenetic analyses suggest that this enrichment possibly
resulted from horizontal gene acquisition followed by multiple internal gene duplication
events. In others symbionts, these gene functions may be substituted by alternate
mechanisms or may not be required at all: The methanotrophic symbionts of B. azoricus,
for example, has the genetic potential to supplement phage defense functions. Thus, the
accessory genomes of Bathymodiolus symbionts are species- or habitat-associated,
possibly facilitating adaptation of the bivalves to their respective micro- and macroenvironments.
In support of this, we show that symbiont biomass in B. thermophilus,
which hosts only one thiotrophic symbiont phylotype, is considerably higher than in B.
azoricus that hosts thiotrophic and methanotrophic symbionts. This suggests that different
symbiont compositions in each species produce distinct microenvironments within the
holobiont.
Our study presents an exhaustive assessment of the genes and proteins involved in this
bivalve-microbe interaction, hinting at intimate host-symbiont interdependencies and
symbiotic crosstalk between partners. The findings open novel prospects for
microbiologists with regard to mechanisms of host-symbiont interplay within highly
specialized niches, origin and distribution of prokaryote-eukaryote interaction factors
across both mutualistic and pathogenic associations.
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.
Oral drug delivery is the preferred route of administration for the majority of drugs. Solid dosage forms arewell-accepted because of ease of administration, accurate dosing and high degree of patient compliance. The orodispersible technology platform has attracted increasing interest. Fast disintegrating in the mouth before swallowing, orodispersible dosage forms like orodispersible tablets (ODTs) address the need for patient-compliant medicines. ODTs represent a convenient alternative to conventional tablets or capsules. ODTs are an interesting approach when a rapid onset of therapeutic action is important. So far, ODTs have often been considered as an innovative variant of conventional oral solid dosage forms. Still, the development of ODT formulations is typically assisted by compendial in vitro test methods. However, the techniques described in international pharmacopoeias are non-specific for ODTs. After administration, the dispersion of an ODT in the mouth may provide effects which might influence the absorption of the drug. The performance of ODTs is more comparable to solutions/suspensions than to traditional tablets. To better guide the development of a new ODT formulation, this lack needs to be addressed. It is the aim of this work to design more specific in vitro test methods helping to improve understanding ODT formulations. To reflect the physiological conditions experienced by an ODT after administration, particular attention was given to the mouth where the ODT disperses and releases the drug before swallowing. In vitro biorelevant test setups simulating in vivo conditions were designed. An electronic tongue system was used to assess taste properties of ODTs. These test methods were applied in different stages of the ODT formulation development. Diclofenac being a poorly soluble and weakly acidic NSAID which is a standard medication for acute painful inflammatory conditions was used as a drug model. Three forms, i.e. the free acid and its sodium/potassium salt, were investigated for the formulation of palatable and fast acting ODTs. In Chapter 1, the development of biorelevant test setup reflecting the physiological conditions experienced by ODTs is described in detail. The newly-designed in vitro models successfully discriminated the different diclofenac forms in successive in vitro compartments simulating the mouth, the stomach and the small intestine. It was possible to identify peculiar dissolution profiles with diclofenac salts. Characterizing in-depth the diclofenac free acid and salt particles provided a better understanding of the peculiar dissolution profiles. Critical behaviors of diclofenac salts on their way from the mouth to the stomach and passing different pH conditions were extensively evaluated. Reasons for pH-dependent API precipitation and particle agglomeration were studied in detail. In pre-formulation studies, the proposed biorelevant test setups succeeded in helping to early identify critical pharmaceutical properties for diclofenac salts and to select diclofenac free acid as the most appropriate drug form providing the most stable in vitro performance. In Chapter 2, the electronic tongue method as an in vitro taste assessment tool for ODTs is proposed. Using the TS-5000Z taste sensing system (Insent Inc., Japan), the method was able to differentiate between the taste/aftertaste qualities and intensities of the three diclofenac candidates. The electronic tongue was also successfully used to differentiate different ODT formulations. The results obtained proved that valuable information can be gained. By this means, the taste perception of the diclofenac drug candidates were classified and rank against each other. For manufacturing taste-masked ODTs, diclofenac free acid, could be selected easily. The electronic tongue found out to be a precious tool in assisting the development of a new ODT product and finding the most appropriate multi-component formulation. Both proposed methods successfully showed their discriminative ability and also their utility in pre-formulation studies of ODTs. In the previous chapters, it was indeed possible to early select diclofenac free acid as the most suitable drug candidate for the targeted product profile. In Chapter 3, said methods were further used to guide the development of the taste masked diclofenac ODT formulation. This study highlights the importance of considering in vitro the physiological aspects which may have an impact on the in vivo performance of ODT dosage forms. The contact of ODTs with the mouth should be simulated in vitro for a better understanding of the in vivo behavior. With feasible biorelevant in vitro dissolution methods, an optimized correlation of in vitro and in vivo results may be achieved. The proposed in vitro test methods may provide data of predictive value and may support the rational development of ODT formulations.
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.
From a biopharmaceutical point of view, poor oral bioavailability of a drug is one of the greatest challenges for formulation scientists. The majority of new chemical entities (NCEs) are weakly basic drugs. Consequently, these drugs exhibit pH-dependent solubility, being higher under acidic conditions in the fasted stomach and lower under neutral conditions in the small intestine, the main site of drug absorption. For theses compounds, pH-dependent precipitation testing represents a key parameter during early development stages. In this development phase, the amount of drug available is limited, and fast and detailed investigations of simulated drug solubility are desired. Therefore, an automated small-scale in vitro transfer model, simulating drug transfer from a donor (stomach; simulated gastric fluid, SGF pH 2.0) to an acceptor (small intestine; fasted state simulated intestinal fluid, FaSSIF-phosphate pH 6.5) compartment, has been developed. In contrast to the originally published transfer model, this model allowed a detailed investigation of drug supersaturation and precipitation in a small-scale, feasible for pre-formulation purposes, through miniaturization and automation in an in-line analytical set-up. In-line drug concentration analysis in turbid samples, due to pH-dependent drug precipitation, was achieved by a pre-filtration step, the use of flow-through cuvettes and the application of UV derivative spectroscopy. Compared to the common procedure of manual sampling followed by HPLC-UV analysis for concentration determination, the supersaturation and precipitation of the model drug ketoconazole was more accurately captured by the newly developed in-line analytical set-up. In addition, the newly developed small-scale model was compared to a USP II-based transfer model, representing an established scale of the transfer model. Using a physiologically relevant simulated gastric emptying rate of 5 min half-time, supersaturation and precipitation of the model drugs ketoconazole and a new chemical entity from the research laboratories of Merck Healthcare KGaA, MSC-A, were observed to be highly comparable. Following miniaturization and automation, the developed small-scale model was used to establish eight physiologically relevant test-sets. These test-sets were used to assess the impact of gastrointestinal (GI) variability, i.e. gastric pH, gastric emptying, and GI fluid volumes, on supersaturation and precipitation of two weakly basic model compounds, ketoconazole and MSC-A. The experiments revealed that variations in all GI parameters investigated affected the in vitro supersaturation and precipitation of ketoconazole. For example, faster gastric emptying yielded higher supersaturation and faster precipitation of ketoconazole. In contrast, MSC-A supersaturation and precipitation was only affected by variability in gastric pH. Consequently, the effect of varying GI parameters was found to be drug-specific. Elevated gastric pH, as it can result from co-medication with acid-reducing drugs, resulted in lower degrees of supersaturation for both substances. For ketoconazole, this result is in agreement with the observation that the oral bioavailability of ketoconazole is lowered when proton pump inhibitors are co-administered. In addition to the physiological considerations, the small-scale model developed herein was used to establish an in vitro screening assay for precipitation inhibitors (PIs). The use of PIs represents one option of reducing the process of pH-dependent drug precipitation during simulated GI transfer. For this purpose, ketoconazole and five orally administered kinase inhibitors (i.e. pazopanib, gefitinib, lapatinib, vemurafenib, and MSC-A) were analyzed with and without the polymeric PIs HPMC, HPMCAS, PVPK17 and K30, PEG6000, and Soluplus® in the small-scale transfer model. This screening revealed that at least one effective PI could be identified for each model drug. Moreover, HPMCAS and Soluplus® were the most effective PIs. Another outcome of these studies was that gefitinib expressed highly variable amorphous precipitation which was confirmed by powder X-ray diffraction (PXRD). During the transfer model experiments, the intermediate amorphous and supersaturated state of gefitinib was stabilized using HPMCAS and Soluplus®. After the polymer investigations, the impact of the buffer species in the simulated intestinal medium on drug supersaturation and precipitation was assessed. Since luminal fluids are mainly buffered by hydrogen carbonate ions, a USP II-based transfer model equipped with the pHysio-grad® device was proposed. This allowed the use of a complex bicarbonate buffer for the preparation of FaSSIF-bicarbonate in an in vitro transfer model. Results of transfer model experiments using standard phosphate-based FaSSIF and a more physiologically relevant bicarbonate-based FaSSIF were compared. Therefore, ketoconazole, pazopanib, and lapatinib were analyzed with and without the precipitation inhibitor HPMCAS. While HPMCAS was found to be an effective precipitation inhibitor for all drugs in FaSSIF-phosphate, the effect in FaSSIF-bicarbonate was much less pronounced. Additionally, performed rat PK studies revealed that HPMCAS did not increase the exposure of any of the model compounds significantly, indicating that the transfer model employing bicarbonate-buffered FaSSIF was more predictive compared to the model using phosphate-buffered FaSSIF. The in vitro and in vivo results of these studies demonstrated that the supersaturation precipitation of poorly soluble weakly basic drugs can be significantly affected by GI variability. Furthermore, the use of the automated small-scale transfer model enabled the identification of effective precipitation inhibitors for the model drugs involved in these studies. At the same time the buffer species has been observed to be especially important to reliably predict the in vivo solubility/dissolution behavior of HPMCAS and the weakly basic model drugs.
With the development of new functional genomics methods that can access the whole genome, transcriptome, proteome and metabolome more comprehensive insights in cellular processes are possible. Largely based on these advances, our knowledge about molecular constituents for many organisms is increasing at a tremendous rate. Until today, the genomes of several organisms including pathogenic bacteria are already sequenced and pave the way for metabolic network constructions. Interest in metabolomics, the global profiling of metabolites in a cell, tissue or organism, has been rapidly increased. A range of analytical techniques, including nuclear magnetic resonance (NMR) spectroscopy, gas chromatography–mass spectrometry (GC–MS), liquid chromatography–mass spectrometry (LC–MS), Fourier Transform mass spectrometry (FT–MS), high performance liquid chromatography (HPLC) are required in order to maximize the number of metabolites that can be identified in a matrix. With the help of microbial metabolomics (qualification and quantification of a huge variety of metabolites from a bacterium) deciphering of the bacterial metabolism is feasible. The metabolome pipeline or workflow encompasses the processes of (i) sample generation and preparation, (ii) establishment of analytical techniques (iii) collection of analytical data, raw data pre-processing, (iv) data analysis and (v) data integration into biological questions. The present work contributes to the above mentioned steps in a metabolomics workflow. A specific focus was set to the exo- and endometabolome analysis of Gram-positive bacteria
The investigation of complex molecular systems by molecular dynamics simulations has been successfully established and proven as a standard method during the last decades. The use of highly optimized algorithms and steadily increasing, generally available computing resources enables even larger and longer simulations. However, the dynamics of the system itself is not accelerated, and it can be trapped in low energy minima that can only be overcome slowly. A number of methods have therefore been developed to address this problem.
Within the context of this dissertation, a novel algorithm based on replica exchange was developed to solve problems with existing methods, which can now be used for large molecular systems with a low resource consumption. Parameter dependence was systematically evaluated and optimized to define guidelines for correct application. This algorithm was successfully applied to various pharmaceutical and biochemical problems, such as protein folding or protein-protein interactions.
Microalgae are aquatic, unicellular, eukaryotic organisms, which perform photosynthesis. They have gained interest within the last decades not only for biofuel production due to their high amount of lipids, but also for pharmaceutical and for nutraceutical purposes. Interesting compounds are proteins, carbohydrates, or pigments, such as carotenoids. However, microalgae possess strong and rigid cell walls, which hinder a sufficient and yet, gentle extraction of those valuable compounds. Although standard extraction techniques are available, several shortcomings occur, e.g. high energy demand, use of environmentally harmful solvents or alteration of compounds due to heat or chemicals. Therefore, an alternative method is needed, which is able to address these disadvantages. Physical plasmas were thus studied to answer the question whether they are able to disintegrate the cell walls of microalgae effectively and yet, without degradation of the extractives.
First step of the thesis was to find a suitable plasma source that has an effect on the cell walls because plasma effects, such as electric fields, shockwaves, UV light emission, and the generation of reactive species can be tailored with the respective setup. It was found that spark discharges are most effective for the extraction of Chlorella vulgaris, which was chosen as model organism. All extraction yields were compared to reference methods, whereat microwave radiation was found to be the most effective reference method and were hence, applied for comparative studies.
For the next step, proteins were selected as targets to answer the question, which differences can be determined between plasms-treated and microwave-radiated proteins are observable although the extraction yields were equal. Furthermore, plasma effects, especially the effects of reactive species on the extracted proteins had to be studied. Findings indicate that heat sensitive proteins, such as photosystem-related proteins, or histones are better extractable with spark discharges than with microwave exposure and the effect of reactive species is only minor.
The last step was to determine, which plasma effect is responsible for the observed cell wall disintegration. Therefore, the tensile strength of Chlorella vulgaris was determined and compared to the shockwave pressure, which is generated from the spark channel. It was proven that the shockwave pressure exceeds by far the tensile strength of the microalgae an can be thus held responsible for mechanism for cell wall rupture.
In this thesis, it was found that spark discharges are a promising alternative for the extraction of valuable compounds from microalgae. The discharges are not only effective, but also gentle enough for sensitive compounds, such as proteins or pigments.
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.
HPMC (Hydroxypropylmethylcellulose) based hydrophilic gel matrix tablets are one of the most commonly used monolithic extended release dosage forms used in the pharmaceutical industry. Drug release from the hydrated HPMC matrix is generally controlled by either diffusion or erosion, or a combination of both. Several studies have shown that for HPMC-based matrices with a high amount of poorly water-soluble additives, erosion is the predominant release mechanism. Erosion rates of these formulations vary significantly with changes in the matrix composition. Depending on the erosion rate, the drug delivery might occur over a shorter or longer time span and thus to different sites of action that are proximal or distal gastrointestinal tract (GIT). Erosion rates of HPMC-based matrices can be modulated by changing the amount and molecular weight of the HPMC. In the present study, four different HPMC-based hydrophilic matrix formulations developed by AstraZeneca R&D, Sweden, were investigated for in vitro as well as in vivo erosion behavior. Formulations F1, F2, and F3 consist of 40% HPMC, which is a mixture of two different HPMC viscosity grades (Methocel K100LV and Methocel K4M). Formulations F1, F2, and F3 contained 23%, 10%, and 0% of Methocel K4M, respectively, while formulation F4 was composed of 20% Methocel K100LV. Calcium hydrogen phosphate dihydrate (a poorly water-soluble compound) was used as the filling excipient. The in vitro HPMC release from the matrices was investigated using a USP dissolution apparatus II equipped with a stationary basket in a phosphate buffer (PB) pH 6.8 and simulated gastric fluid without pepsin (SGFsp) pH 1.2 at various rotation speeds. The HPMC concentration in the dissolution samples were analyzed using size exclusion chromatography coupled with multiangle light scattering and refractive index detectors (SEC-MALS/RI). In order to establish a correlation function between the magnetic moment and HPMC release, the formulations were tested in a magnetic moment dissolution tester (MMDT), a modified in vitro dissolution apparatus equipped with a magnetometer. The in vivo gastrointestinal imaging and erosion behavior of the tablets were investigated by magnetic marker monitoring (MMM) using a superconducting quantum interference devices (SQUIDs) sensor system in five healthy male volunteers at Physikalisch-Technische Bundesanstalt (PTB), Berlin. All formulations were administered after an overnight fast of at least 10 hours. However, formulations 3 and 4 were also administered 30 minutes after a standard FDA breakfast. The in vivo HPMC release was calculated using the correlation function from the recorded in vivo magnetic moment data. A linear correlation function was not observed, since the decrease of the magnetic signal was driven by both erosion and diffusion. The in vitro and in vivo erosion-time profiles show that erosion was strongly dependent on the composition of the formulation. The formulations containing a larger proportion of high molecular weight HPMC, or a higher content of HPMC, exhibited relatively slower erosion rates and vice versa. However, unlike in vitro erosion rates, the in vivo erosion rates for different formulations did not always significantly differ from each other. In vivo erosion rates of the investigated formulations were significantly higher under postprandial administration than under fasted state administration. No rapid disintegration of any of the formulations (that is, formulation failure that can potentially cause dose dumping) was observed. A good linear (point-to-point) correlation between the in vitro HPMC release at 50 rpm in PB pH 6.8 and the in vivo HPMC release was observed for all formulations in the individual volunteers for both administration conditions. The predictability of the in vivo HPMC release for all formulations in fasting as well as postprandial administrations was better with phosphate buffer pH 6.8 at 50 rpm in comparison to SGFsp pH 1.2 or higher stirring rate in phosphate buffer pH 6.8. In postprandial administrations, the gastric emptying time was significantly delayed compared to fasting administrations. For postprandial administrations, the localized erosion rate in the distal stomach was significantly higher than in the proximal stomach. The in vivo HPMC release of the investigated formulations under both intake conditions was not dependent on the motility of the tablet in the gastrointestinal tract. The in vivo HPMC release for all the investigated formulations when administered under fasting conditions was underestimated, while under postprandial conditions, the HPMC release was overestimated by the in vitro dissolution method in PB pH 6.8 at 50 rpm.
The investigated bacterial strain 64G3 was isolated from an offshore oil reservoir in Vung Tau, Vietnam. By means of 16S rDNA sequence alignment and DNA-DNA hybridization with Petrotoga mexicana DSM 14811, the isolate was identified as Petrotoga mexicana species. Morphologically, the 64G3 cells were rod-shaped and cell sizes varied widely from 1.0 µm up to 60 µm in length and from 0.6 to 1.2 µm in width. The cells appeared single, pairwise or in chains within a sheath-like structure (a typical characteristic of the order Thermotogales) that ballooned over the cell ends. Cells were immobile and no flagella were observed. Strain 64G3 grew anaerobically at temperatures ranging from 30 to 65°C and within the pH range of 5.0 to 8.5 with optimum growth at 55°C and the pH 7.0. Elemental sulfur and thiosulfate served as alternative electron acceptors whereas sulfate did not. Cellular extract of strain 64G3 grown in a basal medium containing soluble starch displayed hydrolytic activity towards soluble starch. The amylase system includes at least two individual enzymes. Amylase activity of the cell extract was detected in a wide temperature range (30-80°C), with optimal enzyme activity at 75°C. By using degenerate primer for PCR amplification of GH13 enzyme coding regions in combination with other molecular methods, a full amylase coding gene containing four conserved regions of α-amylase was obtained. The deduced sequence showed low identities (up to 40%) to other known amylases. This 1992 bp coding gene was heterologously expressed in E. coli and its product (amylase) was characterized. Under common expression conditions, the 77 kDa amylase (rAmyA) was predominantly produced as inclusion bodies (insoluble protein). The minor amount of soluble active amylase was used for purification and characterization of the enzyme. rAmyA was active on starch at temperatures between 30-55°C, with an optimum at 45oC. It is not thermostable because it was completely inactive after incubation at 65°C for 15 min. The enzyme was active over a pH range from 4.5-8.0, with an optimum at pH 6.5. Beside starch, rAmyA also hydrolysed glycogen, amylose, amylopectin and other oligosaccharides. Pullulan and cyclodextrins were not the substrates for this amylase. The enzyme hydrolyzed starch in an endo-acting manner, releasing maltose and maltotriose as major products and a lesser amount of glucose. On the basis of the primary structure, the substrate specificities and the hydrolysis pattern, rAmyA was classified as an endo-acting α-amylase (EC. 3.2.1.1). The cpn10/60 operon from psychrophilic O. antarctica was cloned and expressed in B. subtilis using a multi-copy plasmid. The amounts of soluble 60 kDa Cpn60 and 10 kDa Cpn10 produced at temperature ranging from 10 - 30°C were high and stable during cell growth. To investigate the impact of psychrophilic chaperonin on cold adaptation, cells with (cpn+) and without (cpn-) cpn10/60 operon were grown at 10 and 15°C. Growth comparison between two strains revealed that psychrophilic chaperonin did not support cold adaptation of B. subtilis at 10 and 15°C as it did in E. coli. A single copy of O. antarctica cpn10/60 operon was integrated into the amyE locus of the B. subtilis chromosome. The yeast α-glucosidase, a theoretic protein substrate for this chaperonin, was heterologously produced in B. subtilis at temperatures ranging from 15-30°C. Within this temperature range, the major amount of this protein appeared as inclusion bodies. Co-expression of O. antarctica cpn10/60 operon at 15°C, however, did not result in a higher activity of glucosidase. Moreover, SDS-PAGE analysis of cellular insoluble fractions revealed that the amount of insoluble enzyme produced in cpn+ cells did not decrease in comparison with that produced in cpn- cells, indicating that the recombinant chaperonin had no impact on recovery of active α-glucosidase from the inclusion bodies.
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.