@phdthesis{Schmidt2023, author = {Schmidt, Sebastian}, title = {A closer look at long-established drugs: enantioselective protein binding and stability studies}, doi = {10.25972/OPUS-34594}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-345945}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2023}, abstract = {The aim of this work was to investigate older, established drugs. The extent of the protein binding of chiral ephedra alkaloids to AGP and of ketamine to albumin was determined. Since enantiomers of these drugs are individual available, the focus was on possible enantioselective binding and structural moieties involved in the binding. Previously published work suggested that ephedrine and pseudoephedrine can bind stereoselectively to proteins other than albumin in serum. For the determination of the extent of protein binding, the established ultrafiltration with subsequent chiral CE analysis was used. To determine the influence of basicity on binding, the drugs methylephedrine and norephedrine were also analyzed. Drug binding to AGP increased with increasing basicity as follows: norephedrine < methylephedrine < ephedrine < pseudoephedrine. pKaff was determined both graphically using the Klotz plot and mathematical indicating a low affinity of the ephedra alkaloids to AGP. Using STD-NMR spectroscopy experiments the aromatic protons and the C-CH3 side chain were shown to be most strongly involved in binding, which could be confirmed by molecular docking experiments in more detail. For all drugs, van der Waals-, π π , cationic interactions, hydrogen bonds, and a formation of a salt bridge were observed. The individual enantiomers showed no significant differences and thus the binding of ephedra alkaloids to AGP is not significant. In contrast to the ephedra alkaloids, the possible enantioselective binding to albumin was investigated for R and S ketamine. Again, ultrafiltration followed by CE analysis was performed. The binding of ketamine to one main binding site could be identified. A non-linear fit was used for the determination of pKaff. Using the NMR methods STD-NMR, waterLOGSY-NMR, and CPMG-NMRspectroscopy: the aromatic protons as well as the protons of the NCH3 methyl group showed the largest signal intensity changes, while the cyclohexanone protons showed the smallest changes. pKaff was also determined by the change in the chemical shift at different drug-protein ratios. These obtained values confirm the values obtained from ultrafiltration. Based on this, ketamine is classified as a low-affinity ligand to albumin. There were no significant differences between the individual enantiomers and thus the binding of ketamine to albumin is not a stereoselective process. Using statistical design of experiments an efficient chiral CE method for determining the extent of protein binding of R and S ketamine to albumin was developed and validated according to ICH Q2 (R1) guideline. The stability of ketamine was also investigated because a yellowish discoloration of an aqueous solution of ketamine developed under heat. XRPD investigations showed the same crystal structure for all batches examined. An untargeted screening using LC HRMS as well as LC UV measurements showed no degradation of ketamine or the presence of impurities in stress and non-stressed ketamine solutions, confirming the stability of ketamine under the stress conditions investigated. The lower the quality of the water used in the stress tests, the more intense the yellow discoloration occurred. The impurity or the mechanism that causes the yellow discoloration could not be identified.}, subject = {Proteinbindung}, language = {en} } @phdthesis{Moro2011, author = {Moro, Sabrina}, title = {Identification of target proteins of furan reactive metabolites in rat liver}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-57617}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2011}, abstract = {Furan was recently found to be present in a variety of food items that undergo heat treatment. It is known to act as a potent hepatotoxin and liver carcinogen in rodents. In a 2-year bioassay, chronic furan administration to rats was shown to cause hepatocellular adenomas and carcinomas and very high incidences of cholangiocarcinomas even at the lowest furan dose tested (2.0 mg/kg bw). However, the mechanisms of furan-induced tumor formation are poorly understood. Furan is metabolized by cytochrome P450 (CYP) enzymes, predominantly CYP2E1, to its major metabolite cis-2-butene-1,4-dial (BDA). BDA is thought to be the key mediator of furan toxicity and carcinogenicity and was shown to react with cellular nucleophiles such as nucleosides and amino acid residues in vitro. It is well known that covalent protein binding may lead to cytotoxicity, but the cellular mechanisms involved remain to be elucidated. Since covalent binding of reactive intermediates to a target protein may result in loss of protein function and subsequent damage to the cell, the aim of this study was to identify furan target proteins to establish their role in the pathogenesis of furan-associated liver toxicity and carcinogenicity. In order to identify target proteins of furan reactive metabolites, male F344/N rats were administered [3,4-14C]-furan. Liquid scintillation counting of protein extracts revealed a dose-dependent increase of radioactivity covalently bound to liver proteins. After separation of the liver protein extracts by two-dimensional gel electrophoresis and subsequent detection of radioactive spots by fluorography, target proteins of reactive furan intermediates were identified by mass spectrometry and database search via Mascot. A total of 61 putative target proteins were consistently found to be adducted in 3 furan-treated rats. The identified proteins represent - among others - enzymes, transport proteins, structural proteins and chaperones. Pathway mapping tools revealed that target proteins are predominantly located in the cytosol and mitochondria and participate in glucose metabolism, mitochondrial β-oxidation of fatty acids, and amino acid degradation. These findings together with the fact that ATP synthase β subunit was also identified as a putative target protein strongly suggest that binding of furan reactive metabolites to proteins may result in mitochondrial injury, impaired cellular energy production, and altered redox state, which may contribute to cell death. Moreover, several proteins involved in the regulation of redox homeostasis represent putative furan target proteins. Loss of function of these proteins by covalent binding of furan reactive metabolites may impair cellular defense mechanisms against oxidative stress, which may also result in cell death. Besides the potential malfunction of whole pathways due to loss of functions of several participating proteins, loss of function of individual proteins which are involved in various cellular processes such as transport processes across the mitochondrial membranes, cell signaling, DNA methylation, blood coagulation, and bile acid transport may also contribute to furan-induced cytotoxicity and carcinogenicity. Covalent binding of reactive metabolites to cellular proteins may result in accumulation of high amounts of unfolded or damaged proteins in the endoplasmic reticulum (ER). In response to this ER stress, the cell can activate the unfolded protein response (UPR) to repair or degrade damaged proteins. To address whether binding of furan reactive metabolites to cellular proteins triggers activation of the UPR, semiquantitative PCR and TaqMan® real-time PCR were performed. In the case of UPR activation, semiquantitative PCR should show enhanced splicing of X-box binding protein-1 (XBP1) mRNA (transcription factor and key regulator of the UPR) and TaqMan® real-time PCR should determine an increased expression of UPR target genes. However, our data showed no evidence for activation of the UPR in the livers of rats treated either with a single hepatotoxic dose or with a known carcinogenic dose for 4 weeks. This suggests either that furan administration does not induce ER stress through accumulation of damaged proteins or that activation of the UPR is disrupted. Consistent with the latter, glucose-regulated protein 78 (GRP78), identified as a target protein in our study, represents an important mediator involved in activation of the UPR whose inhibition was shown to impair induction of the UPR. Thus, adduct formation and inactivation of GRP78 by furan metabolites may disturb activation of the UPR. In addition to impaired activation of UPR, protein repair and degradation functions may be altered, because several proteins involved in these processes also represent target proteins of furan and thus may show impaired functionality. Taken together...}, subject = {Furan}, language = {en} } @phdthesis{Devine2013, author = {Devine, Eric}, title = {Increased removal of protein bound uremic toxins through reversible modification of the ionic strength during hemodiafiltration}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-83583}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2013}, abstract = {A large number of metabolic waste products accumulate in the blood of patients with renal failure. Since these solutes have deleterious effects on the biological functions, they are called uremic toxins and have been classified in three groups: 1) small water soluble solutes (MW < 500 Da), 2) small solutes with known protein binding (MW < 500 Da), and 3) middle molecules (500 Da < MW < 60 kDa). Protein bound uremic toxins are poorly removed by conventional hemodialysis treatments because of their high protein binding and high distribution volume. The prototypical protein bound uremic toxins indoxyl sulfate (IS) and p-cresyl sulfate (pCS) are associated with the progression of chronic kidney disease, cardiovascular outcomes, and mortality of patients on maintenance hemodialysis. Furthermore, these two compounds are bound to albumin, the main plasma protein, via electrostatic and/or Van-der-Waals forces. The aim of the present thesis was to develop a dialysis strategy, based on the reversible modification of the ionic strength in the blood stream by increasing the sodium chloride (NaCl) concentration, in order to enhance the removal of protein bound substances, such as IS and pCS, with the ultimate goal to improve clinical patient outcomes. Enhancing the NaCl concentration ([NaCl]) in both human normal and uremic plasma was efficient to reduce the protein bound fraction of both IS and pCS by reducing their binding affinity to albumin. Increasing the ionic strength was feasible during modified pre-dilution hemodiafiltration (HDF) by increasing the [NaCl] in the substitution fluid. The NaCl excess was adequately removed within the hemodialyzer. This method was effective to increase the removal rate of both protein bound uremic toxins. Its ex vivo hemocompatibility, however, was limited by the osmotic shock induced by the high [NaCl] in the substituate. Therefore, modified pre-dilution HDF was further iterated by introducing a second serial cartridge, named the serial dialyzers (SDial) setup. This setting was validated for feasibility, hemocompatibility, and toxin removal efficiency. A better hemocompatibility at similar efficacy was obtained with the SDial setup compared with the modified pre-dilution HDF. Both methods were finally tested in an animal sheep model of dialysis to verify biocompatibility. Low hemolysis and no activation of both the complement and the coagulation systems were observed when increasing the [NaCl] in blood up to 0.45 and 0.60 M with the modified pre-dilution HDF and the SDial setup, respectively. In conclusion, the two dialysis methods developed to transitory enhance the ionic strength in blood demonstrated adequate biocompatibility and improved the removal of protein bound uremic toxins by decreasing their protein bound fraction. The concepts require follow-on clinical trials to assess their in vivo efficacy and their impact on long-term clinical outcomes.}, subject = {H{\"a}modiafiltration}, language = {en} }