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Effect of inhalation exposure regimen on DNA binding potency of 1,2-dichloroethane in the rat
(1991)
1 ,2-Dichloroethane (DCE) was reported to be carcinogenic in rats in a long-tenn bioassay using gavage in com oil (24 and 48 mg/kg/day), but not by inhalation (up to 150-250 ppm, 7 h/day, 5 days/week). The daily dose metabolized was similar in the two experiments. In order to address this discrepancy, the genotoxicity of DCE was investigated in vivo under different exposure conditions. Fernale F-344 rats (183-188 g) were exposed to [1,2-14C]DCE in a closed inhalation chamber to either a low, constant concentration (0.3 mg/l = 80 ppm for 4 h) or to a peak concentration (up to 18 mg/1 = 4400 ppm) for a few minutes. After 12 h in the chamber, the dose metabolized under the two conditions was 34 mg/kg and 140 mg/k:g. DNA was isolated from liver and lung and was purified to constant specific radioactivity. DNA was enzymaticaBy hydrolyzed to the 3' -nucleotides which were separated by reverse phase HPLC. Most radioactivity eluted without detectable or with little optical density' indicating that the major part of the DNA radioactivity was due to covalent binding of the test compound. The Ievel of DNA adducts was expressed in the dose-nonnalized units ofthe Covalent Binding Index, CBI = f.Lmol adduct per mol DNA nucleotide/ mmol DCE per kg body wt. In liver DNA, the different exposure regimens resulted in markedly different CBI values of 1.8 and 69, for "constant-low" and ''peak" DCE exposure Ievels. In the Jung, the respective values were 0.9 and 31. It is concluded that the DNA darnage by DCE depends upon the concentration-time profile and that the carcinogenic potency determined in the gavage study should not be used for low-Ievel inhalation exposure.
Mechanistic possibilitles responsible for nonlinear shapes of the dose-response relationship in chemical carcinogenesis are discussed. (i) Induction and saturation of enzymatic activation and detoxification processes and of DNA repair affect the relationship between dose and steady-state DNA adduct Ievel; (ii) The fixation of DNA adducts in the form of mutations is accelerated by stimulation of the cell division, for Jnstance due to regenerative hyperplasia at cytotoxic dose Ievels; (iii) The rate of tumor formation results from a superposition of the rates of the individual steps. It can become exponential with dose if more than one step is accelerated by the DNA damage exerted by the genotoxic carcinogen. The strongly sigmoidal shapes often observed for dose-tumor incidence relationships in animal bioassays supports this analysis. A power of four for the dose in the su~linear part of the curve is the maximum observed (formaldehyde). In contrast to animal experiments, epidemiological data ln humans rarely show a slgnificant deviation from linearity. The discrepancy might be explained by the fact that a I arge nu mber of genes contribute to the overall sensitivity of an individual and to the respective heterogeneity within the human population. Mechanistic nonlinearities are flattened out in the presence of genetic and life-style factors which affect the sensitivity for the development of cancer. For a risk assessment, linear extrapolation from the high-dose lncidence to the spontaneaus rate can therefore be approprlate in a heterogeneous population even if the mechanism of action would result in a nonlinear shape of the dose-response curve in a homogeneaus population.
1 We studied the effect of temperature on the binding to rat heart \(M_2\) muscarinic receptors of antagonists related to the carbon/silicon pairs pridinol/sila-pridinol and diphenidol/sila-diphenidol (including three germanium compounds) and six structurally related pairs of enantiomers [(R)- and (S)-procyclidine, (R)- and (S)-trihexyphenidyl, (R)- and (S)-tricyclamol, (R)- and (S)-trihexyphenidyl methiodide, (R)- and (S)-hexahydro-diphenidol and (R)- and (S)-hexbutinol]. Binding affinities were determined in competition experiments using \([^3H]\)-N-methyl-scopolamine chloride as radioligand. The reference drugs were scopolamine and N-methyl-scopolamine bromide.
2 The affinity of the antagonists either increased or decreased with temperature, van 't Hoff plots were linear in the 278–310°K temperature range. Binding of all antagonists was entropy driven. Enthalpy changes varied from large negative values (down to \(−29 kJ mol^{−1}\)) to large positive values (up to \(+ 30 kJ mol^{−1}\)).
3 (R)-configurated drugs had a 10 to 100 fold greater affinity for \(M_2\) receptors than the corresponding (S)-enantiomers. Enthalpy and entropy changes of the respective enantiomers were different but no consistent pattern was observed.
4 When silanols \((R_3SiOH)\) were compared to carbinols \((R_3COH)\), the affinity increase caused by C/Si exchange varied between 3 and 10 fold for achiral drugs but was negligible in the case of chiral drugs. Silanols induced more favourable enthalpy and less favourable entropy changes than the corresponding carbinols when binding. Organogermanium compounds \((R_4Ge)\) when compared to their silicon counterparts (R4Si) showed no significant difference in affinity as well as in enthalpy and entropy changes.
5 Exchange of a cyclohexyl by a phenyl moiety was associated with an increase or a decrease in drug affinity (depending on the absolute configuration in the case of chiral drugs) and generally also with a more favourable enthalpy change and a less favourable entropy change of drug binding.
6 Replacement of a pyrrolidino by a piperidino group and increasing the length of the alkylene chain bridging the amino group and the central carbon or silicon atom were associated with either an increase or a decrease of entropy and enthalpy changes of drug binding. However, there was no clear correlation between these structural variations and the thermodynamic effects.
7 Taken together, these results suggest that hydrogen bond-forming OH groups and, to a lesser extent, polarizable phenyl groups contribute significantly to the thermodynamics of interactions between these classes of muscarinic antagonists and \(M_2\) muscarinic receptors.
Identifizierung und Strukturaufklärung von Anthocyanen und ihrer Metabolite erfolgten mit Hilfe der mittels Hochleistungsflüssigchromatographie-Diodenarray-Detektion-Elektro-spray-Tan¬dem¬massen¬spektrometrie (HPLC-DAD-ESI-MS/MS). Quantitative Analysen wurden via HPLC-DAD durchgeführt. Die hierzu erforderlichen Referenzverbindungen wurden mittels präparativer HPLC aus Heidelbeeren isoliert (Reinheit zwischen 85,8% und 99,4%). Der Gehalt an Anthocyanen in den untersuchten Heidelbeerfrüchten lag bei 6 g/kg. Bezüglich der mengen¬mäßigen Verteilung dominierten Delphinidin- und Cyanidin¬glykoside vor den Glykosiden von Malvidin, Petunidin und Peonidin. Als konjugierte Zucker¬reste kamen vor allem Glukose und Galaktose vor, der Gehalt an Arabinosiden war weit geringer. Bei oraler Aufnahme erfolgt ein erster Kontakt der Anthocyane mit Speichel. Daher wurde dessen Wirkung auf die Heidelbeeranthocyane in ex vivo-Studien über einen (unphysio-logisch langen) Zeitraum von bis zu 30 Minuten untersucht. Dabei konnte wurde ins-besondere der Einfluß des pH-Wertes auf die Stabilität der Anthocyane aufgezeigt werden. Zur Simulation des Verhaltens von Anthocyanen im Magen wurden die einzelnen Heidelbeeranthocyane mit künstlichem Magensaft (pH 1,81) über vier Stunden inkubiert. Hier erwiesen sich alle untersuchten Verbindungen als stabil. Die anschließend von uns mit simuliertem Duodenalsekret (pH 7,2) über einen Zeitraum von 24 Stunden durchgeführten Studien zeigten, dass die Anthocyane unterschiedlich starken Modifizierungen unterlagen. Unter den schwach alkalischen Bedingungen wurden vor allem die Glykoside des Delphinidins schnell abgebaut, aber auch die übrigen Anthocyane erwiesen sich unter diesen Bedingungen als nicht stabil; nach 24 h war kein Anthocyan mehr nachweisbar. Um die Metabolisierungsvorgänge der Anthocyane im Dünn- und Dickdarm zu untersuchen, wurden ex vivo-Inkubationen jeweils mit frischem Ileo- bzw. Kolo¬stoma-beutel¬inhalt durchgeführt. Während die Abbaugeschwindigkeit in der ilealen Flüssigkeit vor allem von der pH-Stabilität des Aglykons abhänig war, konnten im Dickdarm einzig die Arabinoside nach einer Stunde noch alle in geringen Konzentrationen identifiziert werden. Die meisten Glukoside und Galaktoside waren zu diesem Zeitpunkt schon vollständig abgebaut. Da im Darm von einer hydrolytischen Spaltung der Anthocyane in Anthocyanidin und Zucker ausgegangen wird, wurde die Metabolisierung von Anthocyanidinen unter physio-logischen pH-Bedingungen untersucht. Neben der jeweiligen Spaltung in das Benzoe¬säure-derivat des B-Ringes sowie Phloroglucinessigsäure traten verschiedene Poly¬merisierungs¬-produkte auf, deren Strukturen nicht aufgeklärt werden konnten. In einer weiteren Versuchsreihe wurde die renale Ausscheidung von Anthocyanen bei Ileostomieprobanden nach oraler Applikation von 300 g Heidelbeeren über einen Zeitraum von acht Stunden untersucht. Es zeigte sich, dass ein Stoma des terminalen Ileums keinen Einfluss auf die Absorption und Metabolisierung der Anthocyane hatte. Die Bilanzierung der Anthocyane im Urin erfolgte als Äquvalente von Malvidin-3-O-glukosid, da nicht alle Anthocyanmetabolite zur Verfügung standen. Der Zeitpunkt der maximalen renalen Anthocyanausscheidung sowie die Menge der ausgeschiedenen Anthocyane waren starken interindividuellen Schwankungen unterworfen. Das Aus¬sscheidungs¬maximum (tmax) lag zwischen 0,5 und zwei Stunden. Bei der ausge¬schiedenen Menge wurden Werte zwischen 0,007% und 0.019% der auf¬ge¬nommenen Anthocyane ermittelt. Aufgrund der literaturbekannten Unterschiede zwischen den in Serum und Urin gefunden Anthocyanmengen ist davon auszugehen, dass es nach Anthocyanverzehr zu Inter-aktionen mit Proteinen in Blut oder Geweben kommt. Mittels Blutfraktionierung wurde das humane Serumalbumin (HSA) als wichtigster Bindungspartner der Anthocyane im Blut identifiziert. Anhand spektroskopischer Methoden war es möglich, die Bindungs¬parameter zu berechnen. Als Bindungsort wurde der hydrophile Eingang der lipophilen Warfarin-Bindungstasche in der Subdomäne IIA des HSA-Moleküls mittels "molecular modelling" identifiziert. Nasschemische Untersuchungen ergaben, dass die Bindung der Anthocyane an HSA diese vor ihrem pH-abhängigen Abbau schützt. Eine signifikante Herab¬setzung der chemischen Abbaugeschwindig¬keit konnte auch für bovines Serumalbumin beobachtet werden. Diese Erkenntnis ließ sich auf andere, mit dem HSA-Molekül nicht strukurverwandte lebensmittelrelevante Albumine übertragen. So zeigten Anthocyane große Stabilität in Milch und Eiklar, wobei die Stabilisierung auf eine Wechselwirkung mit den Proteinen Laktalbumin und Ovalbumin zurückgeführt werden konnte. Die in dieser Arbeit erlangten Erkenntnisse hinsichtlich Absorption, Metabolisierung und systemischer Verfügbarkeit im menschlichen Organismus leisten einen Beitrag zum besseren Verständnis der Wirkungen von Anthocyanen. Die neuen Erkenntnisse der Protein¬bindung sind vor allem für die Bewertung der Verfügbarkeit der Anthocyane in humanem Gewebe relevant.
Escape from the host immune system is essential for intracellular pathogens. The adenoviral protein E3-14.7K (14.7K) is known as a general inhibitor of tumor necrosis factor (TNF)-induced apoptosis. It efficiently blocks TNF-receptor 1 (TNFR1) internalization but the underlying molecular mechanism still remains elusive. Direct interaction of 14.7K and/or associated proteins with the TNFR1 complex has been discussed although to date not proven. In our study, we provide for the first time evidence for recruitment of 14.7K and the 14.7K interacting protein optineurin to TNFR1. Various functions have been implicated for optineurin such as regulation of receptor endocytosis, vesicle trafficking, regulation of the nuclear factor kappa B (NF-kappa B) pathway and antiviral signaling. We therefore hypothesized that binding of optineurin to 14.7K and recruitment of both proteins to the TNFR1 complex is essential for protection against TNF-induced cytotoxic effects. To precisely dissect the individual role of 14.7K and optineurin, we generated and characterized a 14.7K mutant that does not confer TNF-resistance but is still able to interact with optineurin. In H1299 and KB cells expressing 14.7K wild-type protein, neither decrease in cell viability nor cleavage of caspases was observed upon stimulation with TNF. In sharp contrast, cells expressing the non-protective mutant of 14.7K displayed reduced viability and cleavage of initiator and effector caspases upon TNF treatment, indicating ongoing apoptotic cell death. Knockdown of optineurin in 14.7K expressing cells did not alter the protective effect as measured by cell viability and caspase activation. Taken together, we conclude that optineurin despite its substantial role in vesicular trafficking, endocytosis of cell surface receptors and recruitment to the TNFR1 complex is dispensable for the 14.7K-mediated protection against TNF-induced apoptosis.
We analyzed rest tremor, one of the etiologically most elusive hallmarks of Parkinson disease(PD), in 12 consecutive PD patients during a specific task activating the locus coeruleus (LC) to investigate a putative role of noradrenaline (NA) in tremor generation and suppression. Clinical diagnosis was confirmed in all subjects by reduced dopamine reuptake transporter (DAT) binding values investigated by single photon computed tomography imaging (SPECT) with [\(^{123}\)I] N-\(\omega\)-fluoropropyl-2 \(\beta\)-carbomethoxy-3 \(\beta\)-(4-iodophenyl) tropane (FP-CIT). The intensity of tremor (i.e., the power of Electromyography [EMG] signals), but not its frequency, significantly increased during the task. In six subjects, tremor appeared selectively during the task. In a second part of the study, we retrospectively reviewed SPECT with FP-CIT data and confirmed the lack of correlation between dopaminergic loss and tremor by comparing DAT binding values of 82 PD subjects with bilateral tremor (n = 27), unilateral tremor (n = 22), and no tremor (n = 33). This study suggests a role of the LC in Parkinson tremor.
The bloodstream developmental forms of pathogenic African trypanosomes are uniquely susceptible to killing by small hydrophobic peptides. Trypanocidal activity is conferred by peptide hydrophobicity and charge distribution and results from increased rigidity of the plasma membrane. Structural analysis of lipid-associated peptide suggests a mechanism of phospholipid clamping in which an internal hydrophobic bulge anchors the peptide in the membrane and positively charged moieties at the termini coordinate phosphates of the polar lipid headgroups. This mechanism reveals a necessary phenotype in bloodstream form African trypanosomes, high membrane fluidity, and we suggest that targeting the plasma membrane lipid bilayer as a whole may be a novel strategy for the development of new pharmaceutical agents. Additionally, the peptides we have described may be valuable tools for probing the biosynthetic machinery responsible for the unique composition and characteristics of African trypanosome plasma membranes.
RNase P processes the 5'-end of tRNAs. An essential catalytic RNA has been demonstrated in Bacteria, Archaea and the nuclei of most eukaryotes; an organism-specific number of proteins complement the holoenzyme. Nuclear RNase P from yeast and humans is well understood and contains an RNA, similar to the sister enzyme RNase MRP. In contrast, no protein subunits have yet been identified in the plant enzymes, and the presence of a nucleic acid in RNase P is still enigmatic. We have thus set out to identify and characterize the subunits of these enzymes in two plant model systems. Expression of the two known Arabidopsis MRP RNA genes in vivo was verified. The first wheat MRP RNA sequences are presented, leading to improved structure models for plant MRP RNAs. A novel mRNA encoding the central RNase P/MRP protein Pop1p was identified in Arabidopsis, suggesting the expression of distinct protein variants from this gene in vivo. Pop1p-specific antibodies precipitate RNase P activity and MRP RNAs from wheat extracts. Our results provide evidence that in plants, Pop1p is associated with MRP RNAs and with the catalytic subunit of RNase P, either separately or in a single large complex.
Flexible behavior is only possible if contingencies between own actions and following environmental effects are acquired as quickly as possible; and recent findings indeed point toward an immediate formation of action-effect bindings already after a single coupling of an action and its effect. The present study explored whether these short-term bindings occur for both, stimulus- and goal-driven actions (“forced-choice actions” vs. “free-choice actions”). Two experiments confirmed that immediate action-effect bindings are formed for both types of actions and affect upcoming behavior. These findings support the view that action-effect binding is a ubiquitous phenomenon which occurs for any type of action.
Although the DNA methyltransferase 2 family is highly conserved during evolution and recent reports suggested a dual specificity with stronger activity on transfer RNA (tRNA) than DNA substrates, the biological function is still obscure. We show that the Dictyostelium discoideum Dnmt2-homologue DnmA is an active tRNA methyltransferase that modifies C38 in \(tRNA^{Asp(GUC)}\) in vitro and in vivo. By an ultraviolet-crosslinking and immunoprecipitation approach, we identified further DnmA targets. This revealed specific tRNA fragments bound by the enzyme and identified \(tRNA^{Glu(CUC/UUC)}\) and \(tRNA^{Gly(GCC)}\) as new but weaker substrates for both human Dnmt2 and DnmA in vitro but apparently not in vivo. Dnmt2 enzymes form transient covalent complexes with their substrates. The dynamics of complex formation and complex resolution reflect methylation efficiency in vitro. Quantitative PCR analyses revealed alterations in dnmA expression during development, cell cycle and in response to temperature stress. However, dnmA expression only partially correlated with tRNA methylation in vivo. Strikingly, dnmA expression in the laboratory strain AX2 was significantly lower than in the NC4 parent strain. As expression levels and binding of DnmA to a target in vivo are apparently not necessarily accompanied by methylation, we propose an additional biological function of DnmA apart from methylation.