In silico Interaktionsanalysen von 17β-Estradiol-Targetstrukturen

Eisold, Alexander

18 April 2019

Micro-pollutants such as 17β-estradiol (E2) have been detected in different water resources and their negative effects on the environment and organisms have been demonstrated. It is essential to confirm the presence of micro-pollutants in different environments by biosensors and to remove these compounds. In this thesis, E2-binding target structures were used to investigate the underlying binding properties. E2-binding protein, DNA-, and PNA-aptamere (peptide nucleic acid) structures were used as targets to determine physicochemical interactions. The protein dataset consist of 35 publicly accessible three-dimensional structures of E2-protein complexes, from which six representative binding sites could be selected. There is no three-dimensional structure information for an E2-specific DNA aptamer, thus it was modeled using a coarse-grained modeling method. Using sequence information additional DNA aptamers were modeled. The E2 ligand was positioned close to the potential binding area of the aptamer structures, the underlying complexes were investigated by a molecular dynamics simulation, and the interactions were examined by an interaction profiler tool for each time step. A PNA generator was developed that can convert DNA and RNA in silico to more robust, but chemically equivalent PNA. This generator was used to transform the E2-specific DNA aptamer into PNA for binding studies with E2. All formed complexes were investigated with respect to the following non-covalent interaction types: hydrogen bonds, water-mediated hydrogen bonds, π-stacking, and hydrophobic interactions. Ten functional groups could be derived which formed the conserved interactions to E2. The study contributes to the understanding of the behavior of ligands that bind through different target structures in an aqueous solution and to the identification of binding specific interaction partners. The results of this thesis can be used to design novel synthetic receptor and filter systems.

info:eu-repo/classification/ddc/540

ddc:540

Estradiol

Schadstoff

Umweltbelastung

Wasseraufbereitung

Chemische Bindung

Aptamer

Elucidation of Unconventional Bonding in Lithium Organic Compounds / Untersuchung unkonventioneller Bindungssituationen in lithiumorganischen Verbindungen

Ott, Holger

28 April 2009

No description available.

540 Chemie

Mathematics and Computer Science

Röntgenbeugung

Quantentheorie der Atome in Molekülen

Lithiumorganische Verbindungen

Picolyllithium

Benzyllithium

Trimethylsilylmethyllithium

X-ray Diffraction

Quantum Theory of Atoms in Molecules

Lithium Organic Compounds

Picolyllithium

Benzyllithium

Trimethylsilylmethyllithium

35.11

35.25

35.44

35.59

35.60

35.90

SP 000: Strukturchemie

STJ 250: Lithium {Anorganische Chemie}

STJ 300: Natrium {Anorganische Chemie}

STL100

Design of Phosphorus Centered Janus Head Ligands / Design phosphorzentrierter Januskopf-Liganden

Objartel, Ina

31 October 2011

No description available.

540 Chemie

Chemistry

Januskopf-Liganden

Di-2-picolylphenylphosphan

Röntgenbeugung

Lithium

Natrium

Zinn

Superbasen

Phosphorane

Janus Head Ligands

Di-2-picolylphenylphosphane

X-ray Diffraction

Experimental Electron Density Studies

Lithium

Sodium

Tin

Superbases

Phosphoranes

35.11

35.25

35.42

35.43

35.44

35.45

35.47

35.59

35.60

STJ 250: Lithium {Anorganische Chemie}

STJ 300: Natrium {Anorganische Chemie}

STM 350: Zinn {Anorganische Chemie}

STN 250: Phosphor {Anorganische Chemie}