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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.
Abstract
The KV7 potassium channel openers flupirtine and retigabine have been valuable options in the therapy of pain and epilepsy. However, as a result of adverse reactions, both drugs are currently no longer in therapeutic use. The flupirtine‐induced liver injury and the retigabine linked tissue discolouration do not appear related at first glance; nevertheless, both events can be attributed to the triaminoaryl scaffold, which is affected by oxidation leading to elusive reactive quinone diimine or azaquinone diimine metabolites. Since the mechanism of action, i. e. KV7 channel opening, seems not to be involved in toxicity, this study aimed to further develop safer replacements for flupirtine and retigabine. In a ligand‐based design strategy, replacing amino substituents of the triaminoaryl core with alkyl substituents led to carba analogues with improved oxidation resistance and negligible risk of quinoid metabolite formation. In addition to these improved safety features, some of the novel analogues exhibited significantly improved KV7.2/3 channel opening activity, indicated by an up to 13‐fold increase in potency and an efficacy of up to 176 % compared to flupirtine, thus being attractive candidates for further development.
KV7 channel openers have proven their therapeutic value in the treatment of pain as well as epilepsy and, moreover, they hold the potential to expand into additional indications with unmet medical needs. However, the clinically validated but meanwhile discontinued KV7 channel openers flupirtine and retigabine bear an oxidation‐sensitive triaminoraryl scaffold, which is suspected of causing adverse drug reactions via the formation of quinoid oxidation products. Here, we report the design and synthesis of nicotinamide analogs and related compounds that remediate the liability in the chemical structure of flupirtine and retigabine. Optimization of a nicotinamide lead structure yielded analogs with excellent KV7.2/3 opening activity, as evidenced by EC50 values approaching the single‐digit nanomolar range. On the other hand, weighted KV7.2/3 opening activity data including inactive compounds allowed for the establishment of structure–activity relationships and a plausible binding mode hypothesis verified by docking and molecular dynamics simulations.
The potassium channel opening drugs flupirtine and retigabine have been withdrawn from the market due to occasional drug-induced liver injury (DILI) and tissue discoloration, respectively. While the mechanism underlying DILI after prolonged flupirtine use is not entirely understood, evidence indicates that both drugs are metabolized in an initial step to reactive ortho- and/or para-azaquinone diimines or ortho- and/or para-quinone diimines, respectively. Aiming to develop safer alternatives for the treatment of pain and epilepsy, we have attempted to separate activity from toxicity by employing a drug design strategy of avoiding the detrimental oxidation of the central aromatic ring by shifting oxidation toward the formation of benign metabolites. In the present investigation, an alternative retrometabolic design strategy was followed. The nitrogen atom, which could be involved in the formation of both ortho- or para-quinone diimines of the lead structures, was shifted away from the central ring, yielding a substitution pattern with nitrogen substituents in the meta position only. Evaluation of KV7.2/3 opening activity of the 11 new specially designed derivatives revealed surprisingly steep structure–activity relationship data with inactive compounds and an activity cliff that led to the identification of an apparent “magic methyl” effect in the case of N-(4-fluorobenzyl)-6-[(4-fluorobenzyl)amino]-2-methoxy-4-methylnicotinamide. This flupirtine analogue showed potent KV7.2/3 opening activity, being six times as active as flupirtine itself, and by design is devoid of the potential for azaquinone diimine formation.
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.
The objectives of this study were to ascertain the fecal ESBL/AmpC-E. coli prevalence and to detect risk factors for their occurrence in young pre-weaned calves and their dams on large dairy farms in Germany. From 2018–2019 we investigated 2816 individual fecal samples from pre-weaned dairy calves and their dams, representing seventy-two farms (mean = 667 milking cows) from eight German federal states. To assess possible risk factors associated with ESBL/AmpC-E. coli prevalence in calves and dams, a questionnaire was performed, collecting management data. We observed an ESBL/AmpC-E. coli prevalence of 63.5% (95% CI: 57.4–69.5) among the sampled calves and 18.0% (95% CI: 12.5–23.5) among the dams. On all farms, at least one positive sample was obtained. To date, this is the highest ESBL/AmpC-E. coli prevalence observed in dairy herds in Europe. Feeding with waste milk was identified as a significant risk factor for a high prevalence of ESBL/AmpC-E. coli in calves. Many calves at large dairies in Germany are fed with waste milk due to the large amounts generated as a result of antibiotic dry-off routines and mastitis treatment with antibiotics. Other notable risk factors for high ESBL/AmpC-E. coli in calves were the general fitness/health of dams and calves, and the quality of farm hygiene. Taken together, these findings suggest that new or improved approaches to animal health management, for example, antibiotic dry cow management (selective dry cow therapy) and mastitis treatment (high self-recovery), as well as farm hygiene, should be researched and implemented.
Seventeen bacterial strains able to suppress plant pathogens have been isolated from healthy Vietnamese crop plants and taxonomically assigned as members of the Bacillus cereus group. In order to prove their potential as biocontrol agents, we perform a comprehensive analysis that included the whole-genome sequencing of selected strains and the mining for genes and gene clusters involved in the synthesis of endo- and exotoxins and secondary metabolites, such as antimicrobial peptides (AMPs). Kurstakin, thumolycin, and other AMPs were detected and characterized by different mass spectrometric methods, such as MALDI-TOF-MS and LIFT-MALDI-TOF/TOF fragment analysis. Based on their whole-genome sequences, the plant-associated isolates were assigned to the following species and subspecies: B. cereus subsp. cereus (6), B. cereus subsp. bombysepticus (5), Bacillus tropicus (2), and Bacillus pacificus. These three isolates represent novel genomospecies. Genes encoding entomopathogenic crystal and vegetative proteins were detected in B. cereus subsp. bombysepticus TK1. The in vitro assays revealed that many plant-associated isolates enhanced plant growth and suppressed plant pathogens. Our findings indicate that the plant-associated representatives of the B. cereus group are a rich source of putative antimicrobial compounds with potential in sustainable agriculture. However, the presence of virulence genes might restrict their application as biologicals in agriculture.
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.
Because of the importance of gastric emptying for pharmacokinetics, numerous methods have been developed for its determination. One of the methods is the salivary tracer technique, which utilizes an ice capsule containing caffeine as a salivary tracer. Despite the ice capsule’s advantage in labeling ingested fluids with caffeine for subsequent salivary detection, its risk of premature melting before swallowing, and its complicated storage and preparation, limit its application, particularly in special populations (e.g., older people). For this reason, here, a compression-coated tablet was developed and validated against the ice capsule in a cross-over clinical trial. The two dosage forms were administered simultaneously to 12 volunteers in an upright position under fasted and fed state conditions. To distinguish the caffeine concentrations in saliva from each dosage form, regular type of caffeine (12C) was added to the tablet, while for the ice capsule 13C3 labelled caffeine was used. The salivary caffeine concentrations showed no statistically significant differences for the pharmacokinetic parameters tmax and AUC0→60 (p > 0.05). Thus, the new formulation is a useful tool for determining gastric emptying that can also be used in special populations.
Bacillus licheniformis is one of the most important hosts used in the biotechnological industry for the production of technical enzymes, antibiotics and a number of biochemicals. Although this bacterium has been used for a long time as an expression host, only little information on expression systems of this host is available. An expression system could be controlled by a cell density signal, a specific chemical inducer or a thermal shift. A limiting substrate such as glucose or phosphate limitation is suggested to use as the signal for the induction of an expression system. When B. licheniformis cells are subjected to nutrient limitation conditions, numerous genes involved in the metabolism of alternative nutrient sources are induced in order to keep cell survival. Therefore, the main topic of this study was to identify and investigate the regulation of genes or operons which are strongly induced in B. licheniformis cells grown under nutrient limitation conditions in order to apply for the construction of potential new expression systems. The research includes studies on the regulation of genes which are responsible for the acetoin and 2,3-butanediol utilization in B. licheniformis cells grown under glucose limitation conditions. Furthermore, we also analyzed the regulation of phytase gene expression as well as investigated the function of a putative ribonuclease expressed in B. licheniformis under phosphate limitation conditions. From this study, it was shown that in B. licheniformis, the utilization of acetoin and 2,3-butanediol was mainly mediated by enzymes encoded by the acoABCL operon. The transcription of this operon was regulated by sigma L transcription factor and was induced by acetoin. The acuABC operon was suggested to play as an indirect regulatory role for the acetoin utilization in B. licheniformis. This operon was controlled by a typical sigma A dependent promoter, however, acetoin was not an inducer for its expression. Furthermore, the regulation of phytase gene expression was suggested to be controlled by PhoPR-two component systems. The results showed that phytate, which is the substrate of phytase enzyme, was not an inducer for the expression of phy gene. However, growth experiments revealed that phytate served as a good alternative phosphate source for the growth of B. licheniformis cells under these conditions. Finally, the inactivation of BLi03719 gene, coding for a putative ribonuclease, resulted in an increase of the total RNA concentration of B. licheniformis cells grown in phosphate limited medium. However, the mutation did not affect the expression of the heterologous reporter gene. Therefore, it could be speculated that the putative ribonuclease BLi03719 plays a role in ribosomal RNA degradation under these conditions.
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.
Klebsiella pneumoniae is a common member of the intestinal flora of vertebrates. In addition to opportunistic representatives, hypervirulent (hvKp) and antibiotic-resistant K. pneumoniae (ABR-Kp) occur. While ABR-Kp isolates often cause difficult-to-treat diseases due to limited therapeutic options, hvKp is a pathotype that can infect healthy individuals often leading to recurrent infection. Here, we investigated the clinical K. pneumoniae isolate PBIO3459 obtained from a blood sample, which showed an unusual colony morphology. By combining whole-genome and RNA sequencing with multiple in vitro and in vivo virulence-associated assays, we aimed to define the respective Klebsiella subtype and explore the unusual phenotypic appearance. We demonstrate that PBIO3459 belongs to sequence type (ST)20 and carries no acquired resistance genes, consistent with phenotypic susceptibility tests. In addition, the isolate showed low-level virulence, both at genetic and phenotypic levels. We thus suggest that PBIO3459 is an opportunistic (commensal) K. pneumoniae isolate. Genomic comparison of PBIO3459 with closely related ABR-Kp ST20 isolates revealed that they differed only in resistance genes. Finally, the unusual colony morphology was mainly associated with carbohydrate and amino acid transport and metabolism. In conclusion, our study reveals the characteristics of a Klebsiella sepsis isolate and suggests that opportunistic representatives likely acquire and accumulate antibiotic resistances that subsequently enable their emergence as ABR-Kp pathogens.
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.
Profiling the activity and hepatotoxicity of flupirtine through medicinal chemistry approaches
(2019)
Drug induced liver injury (DILI) and tissue discoloration led to the recent discontinuation of the therapeutic use of the closely related drugs flupirtine and retigabine, respectively. Experience gained with these drugs strongly suggests that heterodimer, voltage‐gated potassium channels 2 and 3 (KV2/3) are valid targets for effective treatment of pain and epilepsy. Because the adverse effects are not related to the mechanism of action, it appears promising to investigate chemical modifications of these clinically validated, drug‐like leads. In the present retro metabolic drug design study, a series of 44 compounds were
synthesized and characterized with regards to KV7.2/3 opening activity and efficacy. The most active compounds displays excellent potency (EC50 = 4 nM) and efficacy (154%) as an Kv7.2/3 opener. Limited aqeous solubility hampered toxicity testing at concentrations higher than 63 μM, but this concentration was nontoxic to two hepatocellular cell ilnes (HEP‐G2 and TAMH) in culture.
Hypoxia is common in marine environments and a major stressor for marine organisms inhabiting benthic and intertidal zones. Several studies have explored the responses of these organisms to hypoxic stress at the whole organism level with a focus on energy metabolism and mitochondrial response, but the instrinsic mitochondrial responses that support the organelle’s function under hypoxia and reoxygenation (H/R) stress are not well understood. We studied the effects of acute H/R stress (10 min anoxia followed by 15 min reoxygenation) on mitochondrial respiration, production of reactive oxygen species (ROS) and posttranslational modifications (PTM) of the proteome in a marine facultative anaerobe, the blue mussel Mytilus edulis. The mussels’ mitochondria showed increased OXPHOS respiration and suppressed proton leak resulting in a higher coupling efficiency after H/R stress. ROS production decreased in both the resting (LEAK) and phosphorylating (OXPHOS) state indicating that M. edulis was able to prevent oxidative stress and mitochondrial damage during reoxygenation. Hypoxia did not lead to rearrangement of the mitochondrial supercomplexes but impacted the mitochondrial phosphoproteome including the proteins involved in OXPHOS, amino acid- and fatty acid catabolism, and protein quality control. This study indicates that mussels’ mitochondria possess intrinsic mechanisms (including regulation via reversible protein phosphorylation) that ensure high respiratory flux and mitigate oxidative damage during H/R stress and contribute to the hypoxia-tolerant mitochondrial phenotype of this metabolically plastic species.
Synthesis of Quercetin-Loaded Silver Nanoparticles and Assessing Their Anti-Bacterial Potential
(2023)
The study delves into the multifaceted potential of quercetin (Qu), a phytoconstituent found in various fruits, vegetables, and medicinal plants, in combination with silver nanoparticles (AgNPs). The research explores the synthesis and characterization of AgNPs loaded with Qu and investigates their pharmaceutical applications, particularly focusing on antibacterial properties. The study meticulously evaluates Qu’s identity, and physicochemical properties, reaffirming its suitability for pharmaceutical use. The development of Qu-loaded AgNPs demonstrates their high drug entrapment efficiency, ideal particle characteristics, and controlled drug release kinetics, suggesting enhanced therapeutic efficacy and reduced side effects. Furthermore, the research examines the antibacterial activity of Qu in different solvents, revealing distinct outcomes. Qu, both in methanol and water formulations, exhibits antibacterial activity against Escherichia coli, with the methanol formulation displaying a slightly stronger efficacy. In conclusion, this study successfully synthesizes AgNPs loaded with Qu and highlights their potential as a potent antibacterial formulation. The findings underscore the influence of solvent choice on Qu’s antibacterial properties and pave the way for further research and development in drug delivery systems and antimicrobial agents. This innovative approach holds promise for addressing microbial resistance and advancing pharmaceutical formulations for improved therapeutic outcomes.
The microbiome of the colon is characterized by its great diversity. This varies not only intra- but also interindividually and is influenced by endogenous and exogenous factors, such as dietary and lifestyle factors. The aim of this work was to investigate the extent to which the degradation of the drug sulfasalazine is influenced by different microbiota. Therefore, the in vitro model MimiCol3 was used, which represents the physiological conditions of the ascending colon. In addition to a representative physiological volume, the pH value, redox potential and an anaerobic atmosphere are important to provide the bacteria with the best possible growth conditions. Stool samples were taken from three healthy subjects, comparing omnivorous, vegetarian and meat-rich diets, and cultured for 24 h. However, the nutrient medium used for cultivation led to the alignment of the bacterial composition of the microbiota. The previously observed differences between the diets could not be maintained. Nevertheless, the similar degradation of sulfasalazine was observed in all microbiota studied in MimiCol3. This makes MimiCol3 a suitable in vitro model for metabolism studies in the gut microbiome.
Application of In Vivo Imaging Techniques and Diagnostic Tools in Oral Drug Delivery Research
(2022)
Drug absorption following oral administration is determined by complex and dynamic interactions between gastrointestinal (GI) physiology, the drug, and its formulation. Since many of these interactions are not fully understood, the COST action on “Understanding Gastrointestinal Absorption-related Processes (UNGAP)” was initiated in 2017, with the aim to improve the current comprehension of intestinal drug absorption and foster future developments in this field. In this regard, in vivo techniques used for the characterization of human GI physiology and the intraluminal behavior of orally administered dosage forms in the GI tract are fundamental to gaining deeper mechanistic understanding of the interplay between human GI physiology and drug product performance. In this review, the potential applications, advantages, and limitations of the most important in vivo techniques relevant to oral biopharmaceutics are presented from the perspectives of different research fields.
Unveiling the N-Terminal Homodimerization of BCL11B by Hybrid Solvent Replica-Exchange Simulations
(2021)
Transcription factors play a crucial role in regulating biological processes such as cell
growth, differentiation, organ development and cellular signaling. Within this group, proteins
equipped with zinc finger motifs (ZFs) represent the largest family of sequence-specific DNA-binding
transcription regulators. Numerous studies have proven the fundamental role of BCL11B for a
variety of tissues and organs such as central nervous system, T cells, skin, teeth, and mammary
glands. In a previous work we identified a novel atypical zinc finger domain (CCHC-ZF) which
serves as a dimerization interface of BCL11B. This domain and formation of the dimer were shown
to be critically important for efficient regulation of the BCL11B target genes and could therefore
represent a promising target for novel drug therapies. Here, we report the structural basis for
BCL11B–BCL11B interaction mediated by the N-terminal ZF domain. By combining structure
prediction algorithms, enhanced sampling molecular dynamics and fluorescence resonance energy
transfer (FRET) approaches, we identified amino acid residues indispensable for the formation of
the single ZF domain and directly involved in forming the dimer interface. These findings not only
provide deep insight into how BCL11B acquires its active structure but also represent an important
step towards rational design or selection of potential inhibitors.
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.
In many industrial sectors biotechnological production processes have replaced pure chemical methods and allowed new, ecologically friendly and enzyme-based processes. Microorganisms, such as modified Bacillus strains are used in particular for the industrial enzyme synthesis. The two organisms Bacillus licheniformis and Bacillus pumilus are of great industrial importance. B. licheniformis is able to secrete proteins in large amounts, while B. pumilus shows high resistance to oxidative stress. During production processes different conditions can occur that affect the physiology of the production hosts and may result in a quantitative, but also a qualitative impairment of the products. This influence is based on e.g. chemical processes, the setting of temperature, pH, or oxygen availability and can lead to various stress situations for the bacteria. Cells respond to changes in their environment by sensing stressors and initiate a response to the stress, which is usually implemented by an induction or derepression of various regulons. In order to conduct an optimal production process, the metabolism and stress responses of the utilized bacteria should be known exactly. The aim of this study was to analyze of the stress response of B. licheniformis to heat and salt stress, and the stress response of B. licheniformis and B. pumilus to oxidative stress. These analyses were performed at the level of transcriptomics using cDNA microarrays, which is the most direct and global method for the analysis of changes in the physiology of a cell. The identification of stress specific markers genes and their differentiation from the SigB regulated general stress response has been another purpose of this work. Knowledge of these marker genes enables a prompt analysis of the fermentation conditions and thus a possible optimization of the process. The transcriptome analyses of this work show that B. licheniformis responds to heat stress by the induction of heat shock genes belonging to different regulons. These include the htpG gene, the HrcA regulon or the CtsR regulon, encoding chaperones and proteases, which mainly contribute to the protein quality control. The heat stress response of B. licheniformis revealed no fundamental differences to the heat stress response of the Gram-positive model organism Bacillus subtilis. The general stress response (SigB regulon), which is activated by heat stress, could be analyzed in more detail by the study of a ΔsigB mutant of B. licheniformis. Salt stress also provokes a strong induction of the general stress response in B. licheniformis. Genes for the transport and synthesis of compatible solutes were strongly induced, as well as several genes for transport systems with more or less known functions. The synthesis of the osmoprotective metabolites proline and glycine betaine could be verified in more detail by a metabolomics approach. The response to oxidative stress showed differences between both B. licheniformis and B. pumilus, and also to the oxidative stress response of B. subtilis. In B. licheniformis, the genes of the glyoxylate cycle are induced during oxidative stress. An activation of the glyoxylate bypass under oxidative conditions could be confirmed by a metabolome analysis of B. licheniformis. In addition, the PerR regulon of B. licheniformis is extended to include another two genes compared to B. subtilis. In contrast, several genes of the PerR regulon lack in the genome of B. pumilus, such as katA (vegetative catalase) or ahpCF (alkyl hydroperoxide reductase). However, other genes were induced in B. pumilus that were upregulated under oxidative stress conditions neither in B. subtilis nor in B. licheniformis. In addition, known regulons, regulated by e.g. Spx, CtsR or SOS were induced in both organisms. In summary, this dissertation transcriptionally analyzes the stress responses of B. licheniformis to heat, salt and oxidative stress, and in addition the oxidative stress response of B. pumilus. Several stress-specific regulons were identified in both, B. pumilus and B. licheniformis, which also correspond to the stress response of B. subtilis. However, it was possible to additionally assign genes to the stress specific responses of both organisms and to find differences, such as the absence of parts of the PerR regulon of B. pumilus, or the activation of the glyoxylate pathway in B. licheniformis during oxidative stress.
The present study covers the synthesis, purification and evaluation of a novel aminomethacrylate-based copolymer in terms of its suitability for improving the solubility and in vitro release of poorly water-soluble drug compounds. The new copolymer was synthesized by solvent polymerization with radical initiation and by use of a chain transfer agent. Based on its composition, it can be considered as a modified type of dimethylaminoethyl methacrylate-butyl methacrylate-methyl methacrylate “EUDRAGIT® E PO” (ModE). ModE was specifically developed to provide a copolymer with processing and application properties that exceed those of commercially available (co-)polymers in solubility enhancement technologies where possible. By varying the concentration of the chain transfer agent in the radical polymerization process, the molecular weight of ModE was varied in a range of 173–305 kDa. To evaluate the solubility-enhancing properties of ModE, a series of drug-loaded extrudates were prepared by hot melt extrusion using the novel—as well as several commercially available—(co-)polymers. These extrudates were then subjected to comparative tests for amorphousness, solubility-enhancing properties, storage stability, and drug release. Celecoxib, efavirenz, and fenofibrate were used as model drugs in all experiments. Of all the (co-)polymers included in the study, ModE with a molecular weight of 173 kDa showed the best performance in terms of desired properties and was shown to be particularly suitable for preparing amorphous solid dispersions (ASDs) of the three model drugs, which in a first set of dissolution experiments showed better release behavior under pH conditions of the fasting stomach than higher molecular weight ModE types, as well as a variety of commercially available (co-)polymers. Therefore, the results demonstrate the successful synthesis of a new copolymer, which in future studies will be investigated in more detail for universal application in the field of solubility enhancement.
The present study focused on a new formulation approach to improving the solubility of drugs with poor aqueous solubility. A hot melt extrusion (HME) process was applied to prepare drug-loaded solid self-nanoemulsifying drug delivery systems (S-SNEDDS) by co-extrusion of liquid SNEDDS (L-SNEDDS) and different polymeric carriers. Experiments were performed with L-SNEDDS formulations containing celecoxib, efavirenz or fenofibrate as model drugs. A major objective was to identify a polymeric carrier and process parameters that would enable the preparation of stable S-SNEDDS without impairing the release behavior and storage stability of the L-SNEDDS used and, if possible, even improving them further. In addition to commercially available (co)polymers already used in the field of HME, a particular focus was on the evaluation of different variants of a recently developed aminomethacrylate-based copolymer (ModE) that differed in Mw. Immediately after preparation, the L-SNEDDS and S-SNEDDS formulations were tested for amorphicity by differential scanning calorimetry. Furthermore, solubility and dissolution tests were performed. In addition, the storage stability was investigated at 30 °C/65% RH over a period of three and six months, respectively. In all cases, amorphous formulations were obtained and, especially for the model drug celecoxib, S-SNEDDS were developed that maintained the rapid and complete drug release of the underlying L-SNEDDS even over an extended storage period. Overall, the data obtained in this study suggest that the presented S-SNEDDS approach is very promising, provided that drug-loaded L-SNEDDS are co-processed with a suitable polymeric carrier. In the case of celecoxib, the E-173 variant of the novel ModE copolymer proved to be a novel polymeric carrier with great potential for application in S-SNEDDS. The presented approach will, therefore, be pursued in future studies to establish S-SNEDDS as an alternative formulation to other amorphous systems.
Self-nanoemulsifying drug delivery systems (SNEDDS) represent an interesting platform for improving the oral bioavailability of poorly soluble lipophilic drugs. While Liquid-SNEDDS (L-SNEDDS) effectively solubilize the drug in vivo, they have several drawbacks, including poor storage stability. Solid-SNEDDS (S-SNEDDS) combine the advantages of L-SNEDDS with those of solid dosage forms, particularly stability. The aim of the present study was to convert celecoxib L-SNEDDS into S-SNEDDS without altering their release behavior. Various commercially available adsorptive carrier materials were investigated, as well as novel cellulose-based microparticles prepared by spray drying from an aqueous dispersion containing Diacel® 10 and methyl cellulose or gum arabic as a binder prior to their use. Particle size and morphology of the carrier materials were screened by scanning electron microscopy and their effects on the loading capacity for L-SNEDDS were investigated, and comparative in vitro dissolution studies of celecoxib L-SNEDDS and the different S-SNEDDS were performed immediately after preparation and after 3 months of storage. Among the adsorptive carrier materials, the novel cellulose-based microparticles were found to be the most suitable for the preparation of celecoxib S-SNEDDS from L-SNEDDS, enabling the preparation of a solid, stable formulation while preserving the in vitro release performance of the L-SNEDDS formulation.
The poor aqueous solubility of many drug substances has been addressed using different solubility enhancement approaches in the pharmaceutical technology field over the last decades. In this context, advanced drug delivery systems based on lipids referred to as SNEDDS were used to overcome solubility limitations of drugs, that are often associated with a low bioavailability after oral administration. There are numerous examples in the literature for the development of L-SNEDDS, which have led to some pharmaceutical products available on the market. As L-SNEDDS development using conventional methods requires a lot of time and experimental effort, a streamlining of this procedure was aimed in the first part of the presented work.
Starting with the development of L-SNEDDS formulations for solubility enhancement of poorly-water soluble drugs, extensive solubility studies with different BCS Class II drugs were performed in various excipients to determine drugs with high solubilities in these excipients as well as to evaluate multiple excipients for their suitability to be used in L-SNEDDS formulations. Celecoxib, efavirenz and fenofibrate were selected as model drugs and a pre-selection of excipients for further development was made. In a next step, a novel screening approach for L-SNEDDS formulation development based on a customized mapping method in a special triangular mixture design was established. This customized tool for L-SNEDDS development comprised the systematic analysis of results obtained with different in vitro characterization methods such as droplet size analysis and distribution, transmittance measurement and emulsification performance assessment. Furthermore, the novel approach streamlined the procedure for L-SNEDDS development as a reduction of experimental effort and time compared to conventional methods was achieved. The most promising L-SNEDDS formulations determined via the customized screening tool approach showed high drug release of celecoxib, efavirenz as well as fenofibrate, and clearly indicated that this method was suitable for efficiently designing stable and rapidly releasing L-SNEDDS formulations incorporating poorly water-soluble drugs.
After the successful development of L-SNEDDS formulations with different drug substances using the novel screening approach, a further aspect of this work dealt with conversion of L-SNEDDS into S-SNEDDS, since a limited storage stability has been reported for many L-SNEDDS formulations. The conversion into S-SNEDDS required the determination of appropriate solid carriers with different material properties depending on the manufacturing process. As a first technological approach, adsorption to a solid carrier was investigated by adding a carrier to drug-loaded L-SNEDDS applying a defined mixing ratio resulting in a solid, particulate formulation. When performing drug release studies, S-SNEDDS based on different commercial
carrier materials revealed major limitations due to incomplete drug release. Thus, a tailor-made microparticulate carrier material based on cellulose was developed for the purpose of adsorbing L-SNEDDS and presented with superior performance compared to conventional adsorbents based on cellulose or silica. Based on the obtained results, this novel cellulose-based microparticle prepared with gum arabic as a binder was determined to be the most promising material amongst all adsorptive carriers that were investigated.
In addition to the technology approach of adsorption, another manufacturing process was considered in the course of the present work, which focused on the preparation of S-SNEDDS by means of HME. As a successful conversion of L-SNEDDS into S-SNEDDS using HME processing requires at least one additional polymeric component, a selection of marketed (co-)polymers that were frequently used in the field of solubility enhancement were evaluated for their suitability in this context. Critical process parameters and target properties of the (co-)polymers were determined, ultimately leading to the idea of developing a novel, customized polymer in order to perform the conversion step via HME in a more suitable and effective manner. In this context, a new copolymer referred to as ModE, as it disclosed a structural association with the commercially available copolymer EUDRAGIT® E PO, was developed. The novel copolymer ModE was evaluated for its suitability for different formulation technologies and showed promising results when used for S-SNEDDS and ASD formulations prepared by the HME process. Different variants of ModE in terms of Mw, Tg and PDI were synthesized via radical polymerization and it was found that the modification of Mw, Tg and PDI of the novel aminomethacrylate-based copolymer had significant effects on drug release as well as storage stability of S-SNEDDS and ASDs. The ModE copolymer type with a Mw of 173 kDa turned out to be the most suitable candidate for S-SNEDDS development using HME technology. In addition, drug-loaded S-SNEDDS based on the ModE variant 173 kDa were storage stable and presented with the highest drug release among all S-SNEDDS formulations tested.
In conclusion, a novel screening tool approach for efficient L-SNEDDS development was established in order to streamline the process for obtaining stable and rapidly releasing L-SNEDDS formulations which improved the solubility of poorly water-soluble drugs. Apart from the L-SNEDDS development process, the conversion from L-SNEDDS into S-SNEDDS was successfully performed using the technology approaches of adsorption to a solid carrier and HME processing. An improved storage stability compared to L-SNEDDS as well as high drug release were achieved for several S-SNEDDS formulations, especially for those prepared with tailor-made materials. Based on the results obtained for S-SNEDDS formulations produced via adsorption, especially in terms of drug release performance, the new cellulose-based
microparticle carriers (M-GA and M-MC) turned out to be the most suitable materials. S-SNEDDS that were manufactured via HME presented with a superior performance regardless of the incorporated drug when comparing the results of S-SNEDDS with those of the corresponding ASDs regarding drug release performance, amorphicity/crystallinity and storage stability. In this context, among all S-SNEDDS formulations prepared via HME, S-SNEDDS based on the ModE variant 173 kDa showed the best results, especially when using the drug substances celecoxib and efavirenz. Although the S-SNEDDS formulation approach is still largely unexplored, based on the research results generated in the present work, it represents a promising technology platform that should definitely be further developed in future experiments.
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.
Controlling the time point and site of the release of active ingredients within the gastrointestinal tract after administration of oral delivery systems is still a challenge. In this study, the effect of the combination of small capsules (size 3) and large capsules (size 00) on the disintegration site and time was investigated using magnetic resonance imaging (MRI) in combination with a salivary tracer technique. As capsule shells, Vcaps® HPMC capsules, Vcaps® Plus HPMC capsules, gelatin and DRcaps® designed release capsules were used. The three HPMC-based capsules (Vcaps®, Vcaps® Plus and DRcaps® capsules) were tested as single capsules; furthermore, seven DUOCAP® capsule-in-capsule combinations were tested in a 10-way crossover open-label study in six healthy volunteers. The capsules contained iron oxide and hibiscus tea powder as tracers for visualization in MRI, and two different caffeine species (natural caffeine and 13C3) to follow caffeine release and absorption as measured by salivary levels. Results showed that the timing and location of disintegration in the gastrointestinal tract can be measured and differed when using different combinations of capsule shells. Increased variability among the six subjects was observed in most of the capsule combinations. The lowest variability in gastrointestinal localization of disintegration was observed for the DUOCAP® capsule-in-capsule configuration using a DRcaps® designed release capsule within a DRcaps® designed release outer capsule. In this combination, the inner DRcaps® designed release capsule always opened reliably after reaching the ileum. Thus, this combination enables targeted delivery to the distal small intestine. Among the single capsules tested, Vcaps® Plus HPMC capsules showed the fastest and most consistent disintegration.
Fibers and yarns are part of everyday life. So far, fibers that are also used pharmaceutically have mainly been produced by electrospinning. The common use of spinning oils and the excipients they contain, in connection with production by melt extrusion, poses a regulatory challenge for pharmaceutically usable fibers. In this publication, a newly developed small-scale direct-spinning melt extrusion system is described, and the pharmaceutically useful polyvinyl filaments produced with it are characterized. The major parts of the system were newly developed or extensively modified and manufactured cost-effectively within a short time using rapid prototyping (3D printing) from various materials. For example, a stainless-steel spinneret was developed in a splice design for a table-top melt extrusion system that can be used in the pharmaceutical industry. The direct processing of the extruded fibers was made possible by a spinning system developed called Spinning-Rosi, which operates continuously and directly in the extrusion process and eliminates the need for spinning oils. In order to prevent instabilities in the product, further modifications were also made to the process, such as a the moisture encapsulation of the melt extrusion line at certain points, which resulted in a bubble-free extrudate with high tensile strength, even in a melt extrusion line without built-in venting.
Characterization, Chemical Compounds and Biological Activities of Marrubium vulgare L. Essential Oil
(2022)
As consumer trends shift towards more natural and ecological consumption patterns, industrialists are actively working towards substituting synthetic chemicals with natural and vegan products that contain bioactive properties. Thus, considering the shifts in customer demand and the growing concern around vegetable sourced productions, this work aims to contribute to the valorization of aromatic and medicinal Moroccan plants. By focusing on the Marrubium vulgare L. species, our objective is to carry out a physicochemical characterization to determine its chemical composition and biological activities. The volatile fraction collected by hydrodistillation (0.61%) and analyzed by GC-MS (gas chromatography coupled to mass spectrometry) contains five main compounds: 3-Thujanone, Eugenol, Topanol, Menthone and Piperitone. The antioxidant activity has been estimated by applying the DPPH (1,1-diphenyl-2-picrylhydrazyl) free radical scavenging test and the ferric reducing antioxidant power (FRAP). The values of inhibitory concentration prove that our oil is a good antioxidant, with values of IC50 = 1.136 mg/mL and IC50 = 2.998 mg/mL, respectively, for the DPPH and FRAP tests. The results of the antifungal activity indicate a significant inhibition of mycelial growth for both tested molds, as well as a total inhibition of spore production at a concentration of 0.25 µL/mL.
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.
Dermatophytosis, the most prevalent fungal infection, is witnessing a rising incidence annually. To address this challenge, we developed a terbinafine-loaded oil-in-water nanoemulsion (TH-NE) through the aqueous microtitration method. The formulation comprised olive oil (oil phase), Span 80 (surfactant), and propylene glycol (co-surfactant). Pseudo-phase ternary diagrams and thermodynamic studies underscored the stability of TH-NE. Employing the Box–Behnken design (BBD), we optimized TH-NE, which resulted in a remarkable particle size of 28.07 nm ± 0.5, a low polydispersity index (PDI) of 0.1922 ± 0.1, and a substantial negative zeta potential of −41.87 mV ± 1. Subsequently, TH-NE was integrated into a 1.5% carbopol matrix, yielding a nanoemulgel (TH-NEG). Texture analysis of TH-NEG demonstrated a firmness of 168.00 g, a consistency of 229.81 g/s, negative cohesiveness (−83.36 g), and a work of cohesion at −107.02 g/s. In vitro drug release studies revealed an initial burst effect followed by sustained release, with TH-NEG achieving an impressive 88% release over 48 h, outperforming TH-NE (74%) and the marketed formulation (66%). Ex vivo release studies mirrored these results, with TH-NEG (86%) and TH-NE (71%) showcasing sustained drug release in comparison to the marketed formulation (67%). Confocal microscopy illustrated that TH-NEG and TH-NE penetrated to depths of 30 µm and 25 µm, respectively, into the epidermal layer. Furthermore, dermatokinetic studies highlighted the enhanced drug penetration of TH-NEG compared to TH-NE through mouse skin. In summary, our study establishes TH-NEG as a promising carrier for terbinafine in treating dermatophytosis, offering improved drug delivery and sustained release potential.
The goal of this study was to assess the anticancer efficacy of chlorojanerin against various cancer cells. The effects of chlorojanerin on cell cytotoxicity, cell cycle arrest, and cell apoptosis were examined using MTT assay, propidium iodide staining, and FITC Annexin V assay. RT-PCR was employed to determine the expression levels of apoptosis-related genes. Furthermore, docking simulations were utilized to further elucidate the binding preferences of chlorojanerin with Bcl-2. According to MTT assay, chlorojanerin inhibited the proliferation of all tested cells in a dose-dependent manner with a promising effect against A549 lung cancer cells with an IC50 of 10 µM. Cell growth inhibition by chlorojanerin was linked with G2/M phase cell cycle arrest in A549 treated cells. Flow cytometry analysis indicated that the proliferation inhibition effect of chlorojanerin was associated with apoptosis induction in A549 cells. Remarkably, chlorojanerin altered the expression of many genes involved in apoptosis initiation. Moreover, we determined that chlorojanerin fit into the active site of Bcl-2 according to the molecular docking study. Collectively, our results demonstrate that chlorojanerin mediated an anticancer effect involving cell cycle arrest and apoptotic cell death and, therefore, could potentially serve as a therapeutic agent in lung cancer treatment.
In the search for alternative treatment options for infections with multi-resistant germs,
traditionally used medicinal plants are currently being examined more intensively. In this study,
the antimicrobial and anti-biofilm activities of 14 herbal drugs were investigated. Nine of the tested
drugs were traditionally used in Europe for treatment of local infections. For comparison, another
five drugs monographed in the European Pharmacopoeia were used. Additionally, the total tannin
and flavonoid contents of all tested drugs were analyzed. HPLC fingerprints were recorded to ob-
tain further insights into the components of the extracts. The aim of the study was to identify herbal
drugs that might be useable for treatment of infectious diseases, even with multidrug resistant E.
coli, and to correlate the antimicrobial activity with the total content of tannins and flavonoids. The
agar diffusion test and anti-biofilm assay were used to evaluate the antimicrobial potential of dif-
ferent extracts from the plants. Colorimetric methods (from European Pharmacopeia) were used for
determination of total tannins and flavonoids. The direct antimicrobial activity of most of the tested
extracts was low to moderate. The anti-biofilm activity was found to be down to 10 µg mL −1 for
some extracts. Tannin contents between 2.2% and 10.4% of dry weight and total flavonoid contents
between 0.1% and 1.6% were found. Correlation analysis indicates that the antimicrobial and the
anti-biofilm activity is significantly (p < 0.05) dependent on tannin content, but not on flavonoid
content. The data analysis revealed that tannin-rich herbal drugs inhibit pathogens in different
ways. Thus, some of the tested herbal drugs might be useable for local infections with multi-re-
sistant biofilm-forming pathogens. For some of the tested drugs, this is the first report about anti-
biofilm activity, as well as total tannin and flavonoid content.
In the search for alternative treatment options for infections with multi-resistant germs, traditionally used medicinal plants are currently being examined more intensively. In this study, the antimicrobial and anti-biofilm activities of 14 herbal drugs were investigated. Nine of the tested drugs were traditionally used in Europe for treatment of local infections. For comparison, another five drugs monographed in the European Pharmacopoeia were used. Additionally, the total tannin and flavonoid contents of all tested drugs were analyzed. HPLC fingerprints were recorded to obtain further insights into the components of the extracts. The aim of the study was to identify herbal drugs that might be useable for treatment of infectious diseases, even with multidrug resistant E. coli, and to correlate the antimicrobial activity with the total content of tannins and flavonoids. The agar diffusion test and anti-biofilm assay were used to evaluate the antimicrobial potential of different extracts from the plants. Colorimetric methods (from European Pharmacopeia) were used for determination of total tannins and flavonoids. The direct antimicrobial activity of most of the tested extracts was low to moderate. The anti-biofilm activity was found to be down to 10 µg mL−1 for some extracts. Tannin contents between 2.2% and 10.4% of dry weight and total flavonoid contents between 0.1% and 1.6% were found. Correlation analysis indicates that the antimicrobial and the anti-biofilm activity is significantly (p < 0.05) dependent on tannin content, but not on flavonoid content. The data analysis revealed that tannin-rich herbal drugs inhibit pathogens in different ways. Thus, some of the tested herbal drugs might be useable for local infections with multi-resistant biofilm-forming pathogens. For some of the tested drugs, this is the first report about anti-biofilm activity, as well as total tannin and flavonoid content.
The absorption of drugs with narrow absorption windows in the upper small intestine can be improved with a mucoadhesive drug delivery system such as enteric films. To predict the mucoadhesive behaviour in vivo, suitable in vitro or ex vivo methods can be performed. In this study, the influence of tissue storage and sampling site on the mucoadhesion of polyvinyl alcohol film to human small intestinal mucosa was investigated. Tissue from twelve human subjects was used to determine adhesion using a tensile strength method. Thawing of tissue frozen at −20 °C resulted in a significantly higher work of adhesion (p = 0.0005) when a low contact force was applied for one minute, whereas the maximum detachment force was not affected. When the contact force and time were increased, no differences were found for thawed tissue compared to fresh tissue. No change in adhesion was observed depending on the sampling location. Initial results from a comparison of adhesion to porcine and human mucosa suggest that the tissues are equivalent.
Transmucosal drug delivery systems can be an attractive alternative to conventional oral dosage forms such as tablets. There are numerous in vitro methods to estimate the behavior of mucoadhesive dosage forms in vivo. In this work, a tensile test system was used to measure the mucoadhesion of polyvinyl alcohol films. An in vitro screening of potential influencing variables was performed on biomimetic agar/mucin gels. Among the test device-specific factors, contact time and withdrawal speed were identified as influencing parameters. In addition, influencing factors such as the sample area, which showed a linear relationship in relation to the resulting work, and the liquid addition, which led to an abrupt decrease in adhesion, could be identified. The influence of tissue preparation was investigated in ex vivo experiments on porcine small intestinal tissue. It was found that lower values of Fmax and Wad were obtained on processed and fresh tissue than on processed and thawed tissue. Film adhesion on fresh, unprocessed tissue was lowest in most of the animals tested. Comparison of ex vivo measurements on porcine small intestinal tissue with in vitro measurements on agar/mucin gels illustrates the inter- and intra-individual variability of biological tissue.
Antimicrobial resistance is an increasing global problem and complicates successful treatments of bacterial infections in animals and humans. We conducted a longitudinal study in Mecklenburg-Western Pomerania to compare the occurrence of ESBL-producing Escherichia (E.) coli in three conventional and four organic pig farms. ESBL-positive E. coli, especially of the CTX-M type, were found in all fattening farms, confirming that antimicrobial resistance is widespread in pig fattening and affects both conventional and organic farms. The percentage of ESBL-positive pens was significantly higher on conventional (55.2%) than on organic farms (44.8%) with similar proportions of ESBL-positive pens on conventional farms (54.3–61.9%) and a wide variation (7.7–84.2%) on organic farms. Metadata suggest that the farms of origin, from which weaner pigs were purchased, had a major influence on the occurrence of ESBL-producing E. coli in the fattening farms. Resistance screening showed that the proportion of pens with multidrug-resistant E. coli was similar on conventional (28.6%) and organic (31.5%) farms. The study shows that ESBL-positive E. coli play a major role in pig production and that urgent action is needed to prevent their spread.
Natural products comprise a rich reservoir for innovative drug leads and are a constant
source of bioactive compounds. To find pharmacological targets for new or already known
natural products using modern computer-aided methods is a current endeavor in drug discovery.
Nature’s treasures, however, could be used more effectively. Yet, reliable pipelines for the
large-scale target prediction of natural products are still rare. We developed an in silico workflow
Int. J. Mol. Sci. 2020, 21, 7102; doi:10.3390/ijms21197102 www.mdpi.com/journal/ijms
Int. J. Mol. Sci. 2020, 21, 7102 2 of 18
consisting of four independent, stand-alone target prediction tools and evaluated its performance
on dihydrochalcones (DHCs)—a well-known class of natural products. Thereby, we revealed
four previously unreported protein targets for DHCs, namely 5-lipoxygenase, cyclooxygenase-1,
17β-hydroxysteroid dehydrogenase 3, and aldo-keto reductase 1C3. Moreover, we provide a
thorough strategy on how to perform computational target predictions and guidance on using the
respective tools.
Acute pancreatitis is a common clinical inflammatory disease with variable severity from mild, self-limiting attacks to a severe lethal attack with a high mortality. In most of the cases, acute pancreatitis is either caused by gallstone obstruction or excessive alcohol consumption. Clinical symptoms include elevated levels (minimum 3 times than normal) of pancreatic enzymes such as amylase or lipase in serum. It is generally believed that earliest event in acute pancreatitis occur in acinar cells which includes premature protease activation and cytoplasmic vacuole formation. Premature trypsinogen activation has been considered as chief culprit as it can activate other proteases in a cascade like manner in acinar cells. Trypsin activity takes place in a biphasic curve with elevated levels at 1 h and 8 h in the initial stages up to 24 h in caerulein induced pancreatitis in mice. It has been shown that cytoplasmic vacuoles observed in pancreatitis are of autophagic nature. The role of autophagy for the disease onset and its role in trypsinogen is much of a debate. Hence, we studied the relation between autophagosome formation and trypsinogen activation in first 12h of pancreatitis. Although autophagosomes were found to be co-localised with trypsin in vivo, this was found to be a late event occuring only by 4 h. Substrate specific trypsin activity and western blotting from both sub-cellular fractions over the time course of pancreatitis and multiple fractions prepared from 1 h caerulein induced pancreatic tissue revealed that trypsin activity observed at 1 h occured in a zymogen enriched fraction. In line simultaneous confocal imaging of trypsin activity and autophagosome formation in hyperstimulated acini isolated from GFP-LC3 mice showed that both processes are independent and take place in parallel. Furthermore, protease inhibition by gabexate mesilate did not prevent autophagosome formation indicating that trypsinogen activation is not a prerequisite for vacuole formation. Even though, autophagosomes and active trypsin were found to be co-localised around 30 minutes to some degree upon cholecystokinin hyperstimulation, the earliest trypsin activation started to appear by 15 minutes and was independent of autophagosomes. The earliest active trypsin was found to be co-localised along with the cis-Golgi complex suggesting that the Golgi apparatus and its pre-condensed zymogen granules are the compartment responsible for the trypsinogen activation. 2) Protease activation in pancreatic acinar cells considered as the early hallmark event in the acute pancreatitis. However, the disease is aggravated by the infiltration of the leukocytes. Activated proteases mediate acinar cell injury and hereby cause the release of chemokines, which in turn attract inflammatory cells. Transmigrated inflammatory cells cause systemic damage that deteriorates the condition of the disease. Neutrophil elastase has been reported to be involved in the dissociation of cell-cell contact at adherens junctions by the extracellular cleavage of E-cadherin. This subsequently leads to transmigration of leukocytes into the epithelial tissue during the initial phase of experimental pancreatitis and aggravates the disease condition. On the other hand, pancreatic elastase substantially contributes to acinar cell necrosis. In this study, ZD0892, an orally bioavailable dual inhibitor against both elastases was tested for its efficacy to ameliorate severity in acute pancreatitis. ZD0892 orally fed mice showed increased survival compared to the control group in the taurocholate model of severe pancreatitis. In the initial stages of pancreatitis up to 24 h, the severity markers were found to be significantly lower in the inhibitor treated group. Treatment of mice with ZD0892 did not impede the defensive property of the leukocytes such as phagocytosis or oxidative burst. In caerulein induced pancreatitis, a mild form of acute pancreatitis, in rats, the local damage measured as serum amylase and lipase, wet dry ratio, and pancreatic myeloperoxidase levels were significantly lower in the inhibitor group. Systemic inflammatory parameters such as myeloperoxidase activity in lung was found to be significantly lower in the inhibitor fed rats. Inhibitor feeding resulted in lesser elastolytic activity compared to control group indicating that extracellular matrix was less damaged. Prophylactic treatment of pancreatitis with an orally available inhibitor with a dual specificity against pancreatic elastase and PMN-elastase was shown to ameliorate both local and systemic damage. Hence, in overall, ZD0892 treatment is proved to be beneficial to the mice and rats in experimental pancreatitis and should be considered for treatment in humans as the substance has been already studied in phase I and II trails for other indications.