Reversibility of asymmetric catalyzed C–C bond formation by benzoylformate decarboxylase

Kara, Selin, Berheide, Marco, Liese, Andreas

04 January 2016

Benzoylformate decarboxylase (BFD) from Pseudomonas putida catalyzed the formation of 2-hydroxy-1-phenylpropanone (2-HPP), a 2-hydroxy ketone, from the kinetic resolution of rac-benzoin in the presence of acetaldehyde. The formation rate of 2-HPP via kinetic resolution of benzoin was 700-fold lower compared to the formation via direct carboligation of benzaldehyde and acetaldehyde. Further investigations revealed that BFD not only accepts (R)-benzoin but also 2-HPP as the substrate. A typical Michaelis–Menten type kinetics was observed starting from enantiopure (S)- or (R)-2-HPP. The formation of racemic 2-HPP while using benzoin as the donor in the presence of acetaldehyde and the racemization of (R/S)-2-HPP were detected. The equilibrium constant determined, showed favoured conditions towards the product side i.e. (R)-benzoin and 2-HPP. In the end, an extended reaction mechanism was proposed by supplementing the already known mechanism with the C–C bond cleavage activity of BFD towards 2-hydroxy ketones. / Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.

Biotechnologie

Molekular Biotechnologie

Biotechnology

Molecular Biotechnology

Reversibility of asymmetric catalyzed C–C bond formation by benzoylformate decarboxylase

Kara, Selin, Berheide, Marco, Liese, Andreas

04 January 2016

Benzoylformate decarboxylase (BFD) from Pseudomonas putida catalyzed the formation of 2-hydroxy-1-phenylpropanone (2-HPP), a 2-hydroxy ketone, from the kinetic resolution of rac-benzoin in the presence of acetaldehyde. The formation rate of 2-HPP via kinetic resolution of benzoin was 700-fold lower compared to the formation via direct carboligation of benzaldehyde and acetaldehyde. Further investigations revealed that BFD not only accepts (R)-benzoin but also 2-HPP as the substrate. A typical Michaelis–Menten type kinetics was observed starting from enantiopure (S)- or (R)-2-HPP. The formation of racemic 2-HPP while using benzoin as the donor in the presence of acetaldehyde and the racemization of (R/S)-2-HPP were detected. The equilibrium constant determined, showed favoured conditions towards the product side i.e. (R)-benzoin and 2-HPP. In the end, an extended reaction mechanism was proposed by supplementing the already known mechanism with the C–C bond cleavage activity of BFD towards 2-hydroxy ketones. / Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.

Biotechnologie, Molekular Biotechnologie

Biotechnology, Molecular Biotechnology

Transport by kinesin motors diffusing on a lipid bilayer

Grover, Rahul

23 March 2016

Intracellular transport of membrane-bound vesicles and organelles is a process fundamental for many cellular functions including cell morphogenesis and signaling. The transport is mediated by ensembles of motor proteins, such as kinesins, walking on microtubule tracks. When transporting membrane-bound cargo inside a cell, the motors are linked to diffusive lipid bilayers either directly or via adaptor molecules. The fluidity of the lipid bilayers induces loose inter-motor coupling which is likely to impact the collective motor dynamics and may induce cooperativity. Here, we investigate the influence of loose coupling of kinesin motors on its transport characteristics. In the first part of this thesis, we used truncated kinesin-1 motors with a streptavidin-binding-peptide (SBP) tag and performed gliding motility assays on streptavidin-loaded biotinylated supported lipid bilayers (SLBs), so called ‘membrane-anchored’ gliding motility assays. We show that the membrane-anchored motors act cooperatively; the microtubule gliding velocity increases with increasing motor density. This is in contrast to the transport behavior of multiple motors rigidly bound to a substrate. There, the motility is either insensitive to the motor density or shows negative interference at higher motor density, depending on the structure of the motors. The cooperativity in transport driven by membrane-anchored motors can be explained as following: while stepping on a microtubule, membrane-anchored motors slip backwards in the viscous membrane, thus propelling the microtubule in the solution at a velocity, given by the difference of the motor stepping velocity and the slipping velocity. The motor stepping on the microtubule occurs at maximal stepping velocity because the load on the membrane-anchored motors is minute. Thus, the slipping velocity of membrane-anchored motors determines the microtubule gliding velocity. At steady state, the drag force on the microtubule in the solution is equal to the collective drag force on the membrane-anchored motors slipping in the viscous membrane. As a consequence, at low motor density, membrane-anchored motors slip back faster to balance the drag force of the microtubule in the solution. This results in a microtubule gliding velocity significantly lower than the maximal stepping velocity of the individual motors. In contrast, at high motor density, the microtubules are propelled faster with velocities equal to the maximal stepping velocity of individual motors. Because, in this case, the collective drag force on the motors even at very low slipping velocity, is large enough to balance the microtubule drag in the solution. The theoretical model developed based on this explanation is in good agreement with the experimental data of gliding velocities at different motor densities. The model gives information about the distance that the diffusing motors can isotropically reach to bind to a microtubule, which for membrane-anchored kinesin-1 is ~0.3 µm, an order of magnitude higher as compared to rigidly bound motors, owing to the lateral mobility of motors on the membrane. In addition, the model can be used to predict the number of motors involved in transport of a microtubule based on its gliding velocity. In the second part of the thesis, we investigated the effect of loose inter-motor coupling on the transport behavior of KIF16B, a recently discovered kinesin motor with an inherent lipid-binding domain. Recent studies based on cell biological and cell extract experiments, have postulated that cargo binding of KIF16B is required to activate and dimerize the motor, making it a superprocessive motor. Here, we demonstrate that recombinant full-length KIF16B is a dimer even in the absence of cargo or additional proteins. The KIF16B dimers are active and processive, which demonstrates that the motors are not auto-inhibited in our experiments. Thus, in cells and cell extracts Kif16B may be inhibited by additional factors, which are removed upon cargo binding. Single molecule analysis of KIF16B-GFP reveals that the motors are not superprocessive but exhibit a processivity similar to kinesin-1 indicating that additional factors are most likely necessary to achieve superprocessivity. Transport on membrane-anchored KIF16B motors exhibited a similar cooperative behavior as membrane-anchored kinesin-1 where the microtubule gliding velocity increased with increasing motor density. Taken together, our results demonstrate that the loose coupling of motors via lipid bilayers provides flexibility to cytoskeletal transport systems and induces cooperativity in multi-motor transport. Moreover, our ‘membrane-anchored’ gliding motility assays can be used to study the effects of lipid diffusivity (e.g. the presence of lipid micro-domains and rafts), lipid composition, and adaptor proteins on the collective dynamics of different motors.

Molekular Motoren

Molecular motors

Supported Lipid Bilayer

mutli-motor

ddc:570

rvk:WD 5400

Transport by kinesin motors diffusing on a lipid bilayer

Grover, Rahul

25 November 2015

Intracellular transport of membrane-bound vesicles and organelles is a process fundamental for many cellular functions including cell morphogenesis and signaling. The transport is mediated by ensembles of motor proteins, such as kinesins, walking on microtubule tracks. When transporting membrane-bound cargo inside a cell, the motors are linked to diffusive lipid bilayers either directly or via adaptor molecules. The fluidity of the lipid bilayers induces loose inter-motor coupling which is likely to impact the collective motor dynamics and may induce cooperativity. Here, we investigate the influence of loose coupling of kinesin motors on its transport characteristics. In the first part of this thesis, we used truncated kinesin-1 motors with a streptavidin-binding-peptide (SBP) tag and performed gliding motility assays on streptavidin-loaded biotinylated supported lipid bilayers (SLBs), so called ‘membrane-anchored’ gliding motility assays. We show that the membrane-anchored motors act cooperatively; the microtubule gliding velocity increases with increasing motor density. This is in contrast to the transport behavior of multiple motors rigidly bound to a substrate. There, the motility is either insensitive to the motor density or shows negative interference at higher motor density, depending on the structure of the motors. The cooperativity in transport driven by membrane-anchored motors can be explained as following: while stepping on a microtubule, membrane-anchored motors slip backwards in the viscous membrane, thus propelling the microtubule in the solution at a velocity, given by the difference of the motor stepping velocity and the slipping velocity. The motor stepping on the microtubule occurs at maximal stepping velocity because the load on the membrane-anchored motors is minute. Thus, the slipping velocity of membrane-anchored motors determines the microtubule gliding velocity. At steady state, the drag force on the microtubule in the solution is equal to the collective drag force on the membrane-anchored motors slipping in the viscous membrane. As a consequence, at low motor density, membrane-anchored motors slip back faster to balance the drag force of the microtubule in the solution. This results in a microtubule gliding velocity significantly lower than the maximal stepping velocity of the individual motors. In contrast, at high motor density, the microtubules are propelled faster with velocities equal to the maximal stepping velocity of individual motors. Because, in this case, the collective drag force on the motors even at very low slipping velocity, is large enough to balance the microtubule drag in the solution. The theoretical model developed based on this explanation is in good agreement with the experimental data of gliding velocities at different motor densities. The model gives information about the distance that the diffusing motors can isotropically reach to bind to a microtubule, which for membrane-anchored kinesin-1 is ~0.3 µm, an order of magnitude higher as compared to rigidly bound motors, owing to the lateral mobility of motors on the membrane. In addition, the model can be used to predict the number of motors involved in transport of a microtubule based on its gliding velocity. In the second part of the thesis, we investigated the effect of loose inter-motor coupling on the transport behavior of KIF16B, a recently discovered kinesin motor with an inherent lipid-binding domain. Recent studies based on cell biological and cell extract experiments, have postulated that cargo binding of KIF16B is required to activate and dimerize the motor, making it a superprocessive motor. Here, we demonstrate that recombinant full-length KIF16B is a dimer even in the absence of cargo or additional proteins. The KIF16B dimers are active and processive, which demonstrates that the motors are not auto-inhibited in our experiments. Thus, in cells and cell extracts Kif16B may be inhibited by additional factors, which are removed upon cargo binding. Single molecule analysis of KIF16B-GFP reveals that the motors are not superprocessive but exhibit a processivity similar to kinesin-1 indicating that additional factors are most likely necessary to achieve superprocessivity. Transport on membrane-anchored KIF16B motors exhibited a similar cooperative behavior as membrane-anchored kinesin-1 where the microtubule gliding velocity increased with increasing motor density. Taken together, our results demonstrate that the loose coupling of motors via lipid bilayers provides flexibility to cytoskeletal transport systems and induces cooperativity in multi-motor transport. Moreover, our ‘membrane-anchored’ gliding motility assays can be used to study the effects of lipid diffusivity (e.g. the presence of lipid micro-domains and rafts), lipid composition, and adaptor proteins on the collective dynamics of different motors.:Abstract vii 1 Introduction 1 1.1 Intracellular transport driven by motor proteins 2 1.2 Attachment of motor proteins to cargo 13 1.3 In vitro approaches to study transport by motor proteins 16 1.4 Aim of this study 23 2 Transport by kinesin-1 anchored to supported lipid bilayers 24 2.1 Formation and characterization of biotinylated SLBs 26 2.2 Anchoring kinesin-1 to biotinylated SLBs 28 2.3 Gliding motility of microtubules by kinesin-1 linked to SLBs 34 2.4 Theoretical description of gliding motility on diffusing motor proteins 40 2.5 Comparison of the gliding velocity between experiment and theory 46 2.6 Gliding motility on phase-separated SLBs 53 2.7 Discussion 55 3 Transport by KIF16B with an inherent lipid-binding domain 62 3.2 Biophysical characterization of KIF16B 70 3.3 Gliding motility of microtubules by KIF16B linked to SLBs 78 3.4 Transport of SUVs and lipid-coated beads attached to KIF16B 87 3.5 Discussion 90 4 Conclusion and outlook 96 5 Materials and methods 99 5.1 Reagents and solutions 99 5.2 Molecular biology 100 5.3 Protein expression and purification 104 5.4 In vitro motility assays 110 5.5 Image acquisition and data analysis 118 References 126 List of figures 141 List of tables 143 Abbreviations and symbols 144 Acknowledgements 147

info:eu-repo/classification/ddc/570

ddc:570

Molekular Motoren

Katalytische molekular geprägte Polymere : Herstellung und Anwendung in einem Thermistor / Catalytically molecular imprinted polymers : synthesis and application in a thermistor

Lettau, Kristian

January 2007

Biomakromoleküle sind in der Natur für viele Abläufe in lebenden Organismen verantwortlich. Dies reicht vom Aufbau der extrazellulären Matrix und dem Cytoskelett über die Erkennung von Botenstoffen durch Rezeptoren bis hin zur Katalyse der verschiedensten Reaktionen in den Zellen selbst. Diese Aufgaben werden zum größten Teil von Proteinen übernommen, und besonders das spezifische Erkennen der Interaktionspartner ist für alle diese Moleküle äußerst wichtig, um eine fehlerfreie Funktion zu gewährleisten. Als Alternative zur evolutiven Erzeugung von optimalen Bindern und Katalysatoren auf der Basis von Aminosäuren und Nukleotiden wurden von Wulff, Shea und Mosbach synthetische molekular geprägte Polymere (molecularly imprinted polymers, MIPs) konzipiert. Das Prinzip dieser künstlichen Erkennungselemente beruht auf der Tatsache, dass sich funktionelle Monomere spezifisch um eine Schablone (Templat) anordnen. Werden diese Monomere dann vernetzend polymerisiert, entsteht ein Polymer mit molekularen Kavitäten, in denen die Funktionalitäten komplementär zum Templat fixiert sind. Dadurch ist die selektive Bindung des Templats in diese Kavitäten möglich. Aufgrund ihrer hohen chemischen und thermischen Stabilität und ihrer geringen Kosten haben “bio-inspirierte” molekular geprägte Polymere das Potential, biologische Erkennungselemente in der Affinitätschromatographie sowie in Biosensoren und Biochips zu ersetzen. Trotz einiger publizierter Sensorkonfigurationen steht der große Durchbruch noch aus. Ein Hindernis für Routineanwendungen ist die Signalgenerierung bei Bindung des Analyten an das Polymer. Eine Möglichkeit für die markerfreie Detektion ist die Benutzung von Kalorimetern, die Bindungs- oder Reaktionswärmen direkt messen können. In der Enzymtechnologie wird der Enzym-Thermistor für diesen Zweck eingesetzt, da enzymatische Reaktionen eine Enthalpie in einer Größenordnung von 5 – 100 kJ/mol besitzen. In dieser Arbeit wird die Herstellung von katalytisch geprägten Polymeren nach dem Verfahren des Oberflächenprägens erstmalig beschrieben. Die Methode zur Immobilisierung des Templats auf der Oberfläche von porösem Kieselgel sowie die Polymerzusammensetzung wurden optimiert. Weiter wird die Evaluation der katalytischen Eigenschaften über einen optischen Test, sowie das erste Mal die Kombination eines kalorimetrischen Transduktors – des Thermistors – mit der Analyterkennung durch ein katalytisch aktives MIP gezeigt. Bei diesen Messungen konnte zum ersten Mal gleichzeitig die Bindung/Desorption, sowie die katalytische Umwandlung des Substrats durch konzentrationsabhängige Wärmesignale nachgewiesen werden. / Bio macromolecules are responsible in nature for many reactions in living organisms. This reaches from the structure of the extra cellular matrix and the cytoskeleton over the recognition of ligands by receptors up to the catalysis of the most diverse reactions in the cells themselves. These tasks are taken over to the largest part by proteins, and particularly specific recognizing of the interaction partners is extremely important for all these molecules, in order to ensure an error free function. As alternative to the evolutionary production of optimal binders and catalysts on the basis of amino acids and nucleotides, synthetic molecularly imprinted polymer (MIPs) were invented by Wulff, Shea and Moosbach. The principle of these artificial recognition elements is based on the fact that functional monomers specifically arrange themselves around a template. If these monomers are copolymerized with crosslinking monomers, a polymer with molecular cavities is created, in which the functionalities are fixed complementary to the template. Thus the selective binding of the template is possible into these cavities. Due to their high chemical and thermal stability and their small costs "bioinspired" molecularly imprinted polymers have the potential to replace biological recognition elements in affinity chromatography as well as in biosensors and biochips. Despite some published sensor configurations the large break-through is still pending. An obstacle for routine application of is the signal generation on connection of the analyte to the polymer. A possibility for marker-free detection is the use of calorimeters, which can measure heats of reaction or adsorption directly. In enzyme technology the enzyme thermistor is used for this purpose, as enzymatic reactions possess enthalpies in an order of 5 - 100 kJ/mol. In this work the production of catalytically imprinted polymers is described for the first time by the procedure of surface imprinting. The method for immobilization of the template on the surface of porous silicagel as well as the polymer composition were optimized. The evaluation of the catalytic characteristics is shown by an optical test, as well as the first time the combination of a calorimetric transducer - the thermistor - with the analyte recognition by a catalytically active MIP. With these measurements for the first time the binding/desorption, as well as the catalytic transformation of the substrate could be proven at the same time by concentration-dependent heat signals.

Katalyse

molekular geprägte Polymere

Kalorimetrie

Enzymmodelle

Biosensoren

catalysis

molecularly imprinted polymers

calorimetry

enzyme models

biosensors

Life sciences

Dynamics, Ionization and Charge Separation in Superheated Metastable Water / Dynamik, Ionisation und Ladungstrennung in überhitzten metastabilem Wasser

Vöhringer-Martinez, Esteban

03 July 2008

No description available.

540 Chemie

Mathematics and Computer Science

Molekular Dynamik Simulation

überhitztes Wasser

Ladungstrennung

Molecular Dynamics

superheated water

charge separation

35.11

35.21

S

Investigation of Laser-Induced-Liquid-Beam-Ion-Desorption (LILBID) with Molecular Dynamics Simulations

Wiederschein, Frank

13 January 2010

No description available.

530 Physik

Physics

Molekular Dynamik Simulationen

LILBID

Massen Spektrometrie

Molecular Dynamics Simulations

LILBID

Mass Spectrometry

33.10

33.90

RD

Molecular and Elemental Mass Spectrometric Approaches for Monitoring Oxidation Processes in Proteins

Sharar, Mona

06 November 2017

Die oxidative Transformation der Thiol-Gruppe des Cysteins in verschiedene andere funktionelle Gruppen wird als sehr wichtige posttranslationale Modifikation (PTM) angesehen. Cysteinsulfensäure (SA) ist eine Zwischenstufe der Thiol-Oxidation: Sie kann entweder mit freien Thiolen reagieren, um Disulfide zu bilden oder durch reaktive Sauerstoffspezies (reactiveoxygenspecies, ROS) weiter oxidiert werden. Jede Störung des zellulären Redox-Haushalts wird mit altersbedingten Erkrankungen , daher stellt die Überwachung des SA-Spiegels einen vielversprechenden Wegdar, den Status dieses Redox-Haushalts festzustellen. Da bereits kleinste Änderungen der Proteinmengen und PTMs tiefe Einblicke in den Zustand des biologischen Systems liefern können, ist eine quantitative Bestimmung von großer Bedeutung.Technologische Fortschritte im Bereich der Trennungsmethoden und Massenspektrometrie (MS) erlaubten die Entwicklung umfassender Möglichkeiten in der Protein-Analytik. In dieser Arbeit wurde eine neue, hochsensitive und selektive Methode zur Detektion von SA entwickelt. Dafür wurde ein Alkin-β-Ketoester (KE) an einen Lanthanid-haltigen (Ln) Chelatkomplex. Zum Nachweis des Funktionsprinzips wurden, mittels H2O2, Sulfensäuren in verschiedenen Peptidsequenzen erzeugt, um die in biologischen Systemen durch ROS hervorgerufenen Oxidationen nachzustellen. Diese Sulfensäuren wurden anschließend durch den Ln-DOTA-KE-Komplex gebunden. Die Bildung dieser SA-Ln-DOTA-KE-Einheit wurde mittels (Elektronenspray-Ionisation/ ESI-MS) und (induktiv gekoppeltem Plasma/ICP-MS) nachverfolgt. Die entwickelte Methode wurde weiterhin auf die Bestimmung von SA-Bildung in humanem Serum angewandt, humanes Serumalbumin wurde angereichert via Affinitätschromatographie. ICP-MS diente der Bestimmung der SA-Ln-DOTA-KE-Einheit, durch Kombination mit einer Isotopenverdünnungsanalyse (IDA) wurde eine absolute Quantifizierung durchgeführt. Die Ergebnisse zeigen oxidative Schäden bis zu 40 % des vorhandenen Albumins. / Oxidative transformation of cysteine thiol group into different functional groups is considered a significant posttranslational modification (PTM) of great importance. Cysteine sulfenic acid (SA) is the transient state for thiol group oxidation; it can react with free thiols to form disulfide bonds or can be further oxidized with reactive oxygen species (ROS) to form sulfinic and sulfonic acids. As any disturbance in the cellular reduction-oxidation (redox) balance is correlated to age-related diseases, the detection of SA transient state formed a sensor for such redox-mediated events. Whereas only any small change in the quantity of proteins, as well as the formed PTMs, can provide deeper insights into the status of the biological system, quantitative analysis should be carried out to reveal the status of the system. On the other hand, the technological advances, in particular the separation techniques and mass spectrometry (MS), allowed the development of several approaches for the comprehensive assessment of proteome analysis. Herein, we provide a new strategy for the highly sensitive and specific detection of SA using alkyne β-ketoester (KE) previously linked to a lanthanide (Ln)-containing chelator (Ln-DOTA. SA was generated by hydrogen peroxide (H2O2) in different peptide sequences by ROS and was detected by the prepared compound Ln-DOTA-KE. Molecular mass spectrometry (electrospray/ ESI-MS) and (Inductively coupled plasma mass spectrometry /ICP-MS) have been used to monitor the formation of SA linked to Ln-DOTA-KE. The developed strategy has been further applied to the determination of SA-induced formation in human serum by using affinity chromatography for purification of albumin followed by ICP-MS to monitor the formed SA linked to Ln-DOTA-KE in combination with isotope dilution analysis (IDA) for the absolute quantification. Quantitative results showed levels of oxidative damage regarding SA formation in human serum up to 40% of the albumin present.

Molekular Massenspektrometrische

Element Massenspektrometrische

MeCAT

Cysteinsulfensäure

Molecular Analysis

Elemental Analysis

Cysteine - Sulfenic acid

MeCAT

543 Analytische Chemie

VK 8567

VG 9807

ddc:543

Ultracold Rydberg Atoms in Structured and Disordered Environments

Liu, Ivan Chen-Hsiu

14 January 2009

The properties of a Rydberg atom immersed in an ultracold environment were investigated. Two scenarios were considered, one of which involves the neighbouring ground-state atoms arranged in a spatially structured configuration, while the other involves them distributed randomly in space. To calculate the influence of the multiple ground-state atoms on the Rydberg atom, Fermi-pseudopotential was used, which simplified greatly the numerical effort. In many cases, the few-body interaction can be written down analytically which reveals the symmetry properties of the system. In the structured case, we report the first prediction of the formation of ``Rydberg Borromean trimers''. The few-body interactions and the dynamics of the linear A-B-A trimer, where A is the ground-state atom and B is the Rydberg atom, were investigated in the framework of normal mode analysis. This exotic ultralong-range triatomic bound state exists despite that the Rydberg-ground-state interaction is repulsive. Their lifetimes were estimated using both quantum scattering calculations and semi-classical approximations which are found to be typically sub-microseconds. In the disordered case, the Rydberg-excitation spectra of a frozen-gas were simulated, where the nuclear degrees of freedom can be ignored. The systematic change of the spectral shape with respect to the density of the gas and the excitation of the Rydberg atom were found and studied. Some parts of the spectral shape can be described by simple scaling laws with exponents given by the basic properties of the atomic species such as the polarizability and the zero-energy electron-atom scattering length.

Rydberg atom

ultracold physics

atomic and molecular physics

trilobite molecule

borromean molecule

Rydberg atom

ultrakalt Physik

Atom und Molekular Physik

trilobite moleküle

ddc:530

rvk:UM 2160

Molecular characterization of the porcine hyaluronidase gene cluster on SSC13q21 / Molekulargenetische Charakterisierung des porcinen Hyaluronidase-Genclusters auf Chromosom 13q21

Gatphayak, Kesinee

05 February 2004

No description available.

Agricultural Sciences

Schwein

Hyaluronidase-Gen

Chromosom 13

Molekular genetik

TSG-cluster

630 Landwirtschaft

Veterinärmedizin

Pig

Hyaluronidase genes

Chromosome 13

Molecular genetic

TSG-cluster

48.64