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Showing 111 to 116 of 116 (0.021 seconds)Spelling suggestions: "subject:"[een] BIOINORGANIC"" "subject:"[enn] BIOINORGANIC""
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AN UNDERSTANDING OF MUSSEL ADHESION TO INFLUENCE MATERIALS DEVELOPMENTSamuel L Huntington (8983913) 12 October 2021 (has links)
<p>The development of new materials
has been inspired by lessons learned from natural systems. In the area of
underwater adhesion and adhesives, inspiration has come from the complex
protein adhesives generated by marine organism such as barnacle and mussels.
These protein systems have a high incorporation of a unique amino acid, dihydroxyphenylalanine,
and provides the unique adhesive qualities synthetic systems strive to emulate.</p>
<p>By understanding how marine mussels
stick to a variety of surfaces, new strategies can be explored for preventing
the adhesion of biological organisms to various substrates. A continuous
concern for marine vessels is the detrimental impact caused by biofouling on
the hull of the ship. Fuel consumption can increase as the vessel’s drag
increasing fuel consumption and non-native species can be introduced into new environments.
Taking inspiration from catechol curing, new oxidative surfaces were investigated
as potential antifouling coatings.</p>
<p>Further insight into the marine
mussels ability to apply and cure its adhesive on a variety of substrate has
also inspired various synthetic polymers. The catechol moiety can be
incorporated into a polymer backbone to give a new solvent based adhesive. Further
investigation of the poly(styrene-co-(3,4-dihydroxystyrene)) adhesive system was
done to formulate an underwater adhesive for unique use cases. A terpolymer was
also explored as an ideal adhesive taking inspiration from the mussels by
incorporating flexible, stiff, and sticky components to give a tunable adhesive.</p>
<p>Having a strong bonding synthetic
adhesive that can be used on a laboratory scale is good for academic
investigation, but not of use outside the lab if it cannot easily be produced
on a commercial scale. With the goal of large scale synthesis, a new
polymerization method was introduced addressing some of the issues currently preventing
commercial scale production.</p><br>
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Entwicklung von funktionalen biomimetischen Modellen für mononukleare Nicht-Häm-Eisenenzyme und ihre ReaktionsmechanismenMüller, Lars 17 December 2021 (has links)
In der vorliegenden Arbeit werden unter Verwendung von Hydrotris(pyrazolyl)-boraten (Tp) als tripodale Zuschauerliganden Modellsysteme für unterschiedliche Nicht-Häm-Eisenenzyme entwickelt und untersucht. Dabei steht im ersten Schritt die Syntheseoptimierung und Implementierung der noch nicht für biomimetische Studien verwendeten TpMes und TpMes* Liganden im Vordergrund. Darauffolgend werden geeignete Metall-Chloro-Vorläuferkomplexe [TpMesMCl] synthetisiert. Das Koordinationsverhalten des TpMes*-Liganden gegenüber zweiwertigen Übergangsmetallionen wird systematisch untersucht und eine Reihe von heteroleptischen [TpMes*MCl] und homoleptischen [(TpMes*)2M] Komplexen synthetisiert und charakterisiert.
Die Modellverbindungen [TpMesFeCysOEt] und [TpMesFeCysAm], welche Cysteinatethylester und Cysteaminat als Substratliganden tragen, dienen jeweils als strukturelles sowie funktionelles Modell für die Cystein- und die Cysteamindioxygenase. Die Mesitylreste des TpMes-Liganden bilden eine schützende, becherartige Struktur um das Eisenzentrum. Die Reaktionsprodukte können so unter anderem erstmalig kristallografisch charakterisiert werden. Zudem wird ein Intermediat in der Reaktion von [TpMes*FeCysAm] mit O2 beobachtet und eingehend untersucht.
Die Eisen(II)komplexe [TpMesFeOBzR], die neben dem Tp-Liganden unterschiedlich substituierte Benzoate tragen, zeigen bemerkenswerte Ähnlichkeit zum Ruhezustand von Lipoxygenasen. Mit tert-Butylhydroperoxid (tBuOOH) können temperaturempfindliche Spezies beobachtet werden, die den mononuklearen [TpMesFe(OOtBu)(OBzR)] Alkylperoxiden zugeordnet werden.
Im letzten Teil dieser Arbeit wird [TpMesFeACC] als Modell für die 1-Aminocyclopropansäureoxidase dargestellt. Es ist möglich, reaktive Spezies mit tBuOOH und meta-Chlorperbenzoesäure (mCPBA) zu beobachten. Zudem liefert die elektrochemische in-situ-Aktivierung von Sauerstoff in Folge Hinweise auf (Hydro-)-peroxidkomplexe bei der Reaktion von [TpMesFeACC] mit dem Superoxidradikalanion. / In the present work model systems for different non-heme iron enzymes are developed and investigated with the help of hydrotris(pyrazolyl) borates (Tp) as tripodal spectator ligands. The first part focusses on the optimization of the synthesis and implementation of the TpMes and TpMes* ligands for biomimetic studies. Following this, suitable precursor complexes [TpMesMCl] are prepared. The coordination behavior of the so far rarely used TpMes* ligand towards divalent transition metal ions is systematically investigated and several heteroleptic [TpMes*MCl] and homoleptic [(TpMes*)2M] complexes are synthesized and characterized.
The model complexes [TpMesFeCysOEt] and [TpMesFeCysAm], which carry cysteinate ethylester and cysteaminate as substrate ligands, serve as structural and functional models for the cysteine and cysteamine dioxygenase, respectively. The mesityl residues of the TpMes ligand form a protective, cup-like structure around the iron center. The reaction products could be characterized crystallographically for the first time. An intermediate in the reaction of [TpMes*FeCysAm] with O2 is intensively studied.
The iron(II) complexes [TpMesFeOBzR], which in addition to the Tp ligand carry substituted benzoates, show remarkable similarities to the resting state of lipoxygenases. With tert-butyl hydroperoxide (tBuOOH) temperature-sensitive species are observed, which are assigned to the mononuclear [TpMesFe(OOtBu)(OBzR)] alkylperoxides.
In the last part of this work, [TpMesFeACC] is presented as a model for 1-aminocyclopropan-1-carboxylic acid oxidase. It is possible to observe reactive species with tBuOOH and meta-chloroperbenzoic acid (mCPBA). In addition, the electrochemical in-situ activation of oxygen provides evidence for (hydro-)peroxide complexes in the reaction of [TpMesFeACC] with the superoxide radical anion.
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New Biomimetic Analogues of Functional [2Fe-2S] Proteins / Neue biomimetische Analoga von funktionellen [2Fe-2S] ProteinenBallmann, Hans Joachim 29 October 2008 (has links)
No description available.
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Biomimetic and Theoretic Investigations of Unusual Iron-Sulphur Clusters / Biomimetische und Theoretische Untersuchungen ungewöhnlicher Eisen-Schwefel-ClusterFuchs, Michael Günther Georg 21 October 2009 (has links)
No description available.
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Biomimetic Studies on Tyrosine- and Phenolate- Based Ligands and their Metal ComplexesUmayal, M January 2014 (has links) (PDF)
Tyrosine (4-hydroxyphenylalanine) is one of the naturally occurring 22 amino acids. The importance of tyrosine is due to the presence of its phenolic side chain. In biological systems, the tyrosyl residue in proteins is found to be sulfated, phosphorylated and nitrated. Upon oxidation with dioxygenases, Tyr residue forms dopaquinone which undergoes a series of reactions ultimately leading to the formation of melanin. Tyr is also a precursor to neurotransmitters (catechol amines namely dopamine, epinephrine and norepinephrine) and thyroid harmones T4 and T3. Tyr residue is also found to be cross linked with other amino acid residues in the active site of certain proteins. Tyr-Tyr cross link has also been associated with neurodegenerative diseases. Tyr residue in proteins has been targeted widely for site selective modifications. A series of chemical modifications like acylation, allylation, ene-type reaction, iodination with radiolabeled iodine, formation of Tyr-Tyr cross link with oxidants and aminoalkylation have been carried out on surface exposed Tyr residues in proteins. Apart from these chemical modifications of Tyr on protein surface, a couple of free Tyr-based scaffolds have also been developed for different applications. Similar to tyrosine-based scaffolds, several phenolate-based scaffolds have also been developed for various applications. Several phenolate-based binuclear metal complexes have been developed as mimics of the active site of metalloenzymes. Moreover, by varying the substituent in the phenolate scaffold, the redox properties of metal bound in these systems can be tuned.
The thesis consists of five chapters. The first chapter gives general idea about tyrosine-and phenolate-based scaffolds. The first chapter also gives introduction to zinc(II)-containing enzymes metallo-β-lactamases (mβls) and phosphotriesterase (PTE) and their functional mimics. The importance of copper(II)-containing enzyme, catechol oxidase and its mimics has also been discussed. The significance and formation of o-dityrosine (Tyr-Tyr cross link) has also been briefly discussed. In chapters 2 and 3, a couple of phenolate-based ligands and their corresponding zinc(II)- and copper(II)- complexes have been synthesized and have been checked as mimics of zinc(II)-containing enzymes (mβl and PTE) and copper-containing enzyme catechol oxidase, respectively. In chapter 4, a series of tyrosine-based ligands have been designed and their in situ copper(II) complexes have been tested as mimics of catechol oxidase.
In chapter 5, the effect of neighboring amino acid in the formation of Tyr-Tyr cross link has been studied.
In chapter 2, a couple of zinc(II) complexes have been synthesized and studied as mimic of zinc(II)-containing enzymes mβl and PTE. Metallo-β-lactamases (mβls) are zinc(II)-containing enzymes which exist in both mono- and binuclear forms. Mβls are capable of hydrolyzing β-lactam ring in antibiotics and make them inactive (Scheme 1(A)). To date, an effective inhibitor for this enzyme is not known. Hence, in order to understand the nature of the enzyme a couple of synthetic mimics are known. However, in most of the synthetic mimics both the metal ions are in symmetrical environment. Therefore, we have attempted to design a few unsymmetrical phenolate- based ligands and their zinc(II) complexes. The unsymmetrical phenolate-based ligands HL1 and HL2 have been synthesized by sequential mannich reaction with formaldehyde and two different amines. Complexes 1 and 2 are obtained from ligands HL1 and HL2, respectively (Figure 1). For comparative purpose, the symmetrical ligands HL3 and HL4, and their zinc(II)-complexes 3 and 4 have been synthesized by reported procedures (Figure 1). The efficiency of the complexes 1-4 towards the hydrolysis of oxacillin has been studied. It has been observed that the binuclear zinc(II) complexes with metal-bound water molecule 1 and 4 are able to hydrolyze oxacillin at much faster rates compared to that of mononuclear complexes 2 and 3. However, between 1 and 4, there is no appreciable change in activity, indicating that the slight change in ligand environment has no significant role.
PTE is a binuclear zinc(II)-containing enzyme, capable of hydrolyzing toxic organphosphotriesters to less toxic diesters (Scheme 1(B)). As the binuclear active site of mβl is comparable with that of phosphotriesterase (PTE), PTE activity of complexes 1-4 has been studied. Although the binuclear zinc(II)-complexes 1 and 4 are able to hydrolyze PNPDPP (p-nitrophenyl diphenyl phosphate) initially, these complexes are not able to effect complete hydrolysis. This is due to the inhibition of complexes 1 and 4 by hydrolyzed product, diester. However with mononuclear complexes 2 and 3 no such inhibitions is possible, and are capable of hydrolyzing PNPDPP at comparatively faster rates than 1 and 4.
Scheme 1. Function of metallo-β-lactamase and phosphotriesterase. (A) Hydrolysis of β-lactam ring in antibiotics by metallo-β-lactamase. (B) Hydrolysis of organophosphotriesters to diesters by phosphotriesterase.
Figure 1. Chemical structures of ligands HL1-HL4 and their corresponding zinc(II)complexes 1-4.
In chapter 3, a couple of copper(II) complexes have been synthesized and their catechol oxidase activity has been studied. Catechol oxidase belongs to the class of oxidoreductase and it catalyzes the oxidation of a wide range of o-diphenols to o-quinones through the reduction of molecular oxygen to water (Scheme 2). A four new µ4-oxo-bridged tetranuclear copper(II) complexes (5-8) have been synthesized (Figure 2). The ability of these complexes to catalyze the oxidation of 3,5-DTBC (3,5-Di-tert-butylcatechol) to 3,5-DTBQ (3,5-Di-tert-butylquinone) has been studied. A detailed kinetic study has been carried out which reveals that the complexes with exogenous acetate ligands (5 and 6) are better catechol oxidase mimics compared to complexes with exogenous chloride ligands (7 and 8). This observation is due to the labile nature of acetate compared to chloride, as the displacement of exogenous ligand is essential for the binding of substrate to the catalyst. Based on mass spectral analysis a plausible mechanism has been proposed for the oxidation of 3,5-DTBC by these complexes.
Scheme 2. Oxidation of catechol by catechol oxidase.
Figure 2. Chemical structures of copper(II) complexes 5-8.
In chapter 4, by following the analogy between phenol and tyrosine, a series of binucleating ligands of tyrosine or tyrosyl dipeptides (Figures 3 and 4) have been synthesized by Mannich reaction under mild conditions. The in situ complexation of these fifteen new binucleating ligands (HL5-HL19) with copper(II) chloride has been observed. In situ complexation was followed by UV-visible and mass spectral analysis. These in situ complexes were able to oxidize 3,5-DTBC at slower rate compared to that of the tetranuclear complexes reported in chapter 3. The catecholase activity has also been tested with the addition of base. A slight enhancement in activity of in situ complexes has been observed in the presence of base. Based on mass spectral evidences, a plausible mechanism for the oxidation of catechol by these in situ complexes has been proposed.
Figure 3. Binucleating ligands (Mannich bases) of boc-protected tyrosine and tyrosyl dipeptides.
Figure 4. Binucleating ligands (Mannich bases) of boc-deprotected tyrosyl dipeptides.
In chapter 5 of the thesis, the effect of neighboring amino acid residue in the formation of o,o-dityrosine (Tyr-Tyr cross link) has been studied. o,o’-Dityrosine is a specific marker for oxidative/nitrosative stress. The increase in concentration of dityrosine is associated with several disease states. A detailed study has been carried out in order to find out the effect of neighboring amino acid residues in the rate of formation of dityrosine of several tyrosyl dipeptides. The formation of dityrosine has been carried out with horseradish peroxidase(HRP) and H2O2
(Scheme 3). Except Cys-Tyr, all other tyrosyl dipeptides, form corresponding dityrosine with HRP/ H2O2. With Cys-Tyr, the formation of corresponding disulfide is observed. The appreciably higher rate of dityrosine formation of Phe-Tyr is attributed to the presence of strong hydrophobic environment around the active site of HRP. Among the polar tyrosyl peptides, the positively charged peptides (Arg-Tyr, Lys-Tyr) undergo dityrosine formation at much faster rate compared to that of negatively charged dipepptides (Asp-Tyr, Glu-Tyr). This trend is in accordance with the pKa of neighboring amino acid residues. The positively charged neighboring residues with higher pKa stabilizes ionized tyrosine, hence the rate of dityrosine formation is higher for them. As positively charged neighboring residue enhances the rate of dityrosine formation, the effect of externally added L-Arg has been studied. A coupling of a few biologically relevant tyrosine derivatives has been studied. The derivatives in which one of the ortho-positions of tyrosine is blocked, does not undergo coupling under the experimental conditions employed.
Scheme 3. Formation of dityrosine of Ile-Tyr from Ile-Tyr in the presence of H2O2 catalyzed by HRP.
(For structural formula and figures pl refer the abstract pdf file)
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Interaccions entre ions metàl·lics i composts d'interès biològic (halouracils i derivats sintètics, hipurats i aciclovir). Interacciones metàl·liques que desenvolupen noves molècules anticancerosesBarceló Oliver, Miquel 27 March 2009 (has links)
La química bioinorgánica se ocupa de estudiar la función de los metales en los sistemas biológicos y de la síntesis de modelos para estudiar sistemas más complejos. Enmarcados en esta, se han estudiado los modos de interacción y los patrones de reconocimiento presentes en los complejos ternarios metal - base nitrogenada - derivado de aminoácido. En primer lugar, se han obtenido un serie de complejos binarios de 5-halouracilatos con cobre(II), zinc(II) y níquel(II) que presentan un reconocimiento por tándem de enlaces de hidrógeno entre uracilos. Con ácido orto-iodohipúrico se han preparado una serie de complejos binarios con cobalto(II), níquel(II), cobre(II), zinc(II) y plata(I). Con estos y aciclovir se ha conseguido la formación de los complejos ternarios donde los de cobalto, níquel y zinc son isoestructurales y, debido a la presencia de un apilamiento entre el aciclovir y un anillo aromático de o-iodohipúrico, se generan en la estructura los dos enantiómeros δ (delta minúscula) y λ (lambda minúscula) si consideramos los dos ligandos como un quelato gracias a la interacción por apilamiento. Con cobre(II), ácidos hipúricos y 1,10-fenantrolina o 2,2'-bipiridilo se han preparado una serie de complejos ternarios capaces de generar la especie de cobre(I) [Cu(phen)2]+ y que presentan actividad anticancerosa frente a células A549. En todos los complejos con ácidos hipúricos se ha observado que la presencia del anillo aromático perpendicular al plano amídico genera estructuras bidimensionales, mientras que con ligandos planares del mismo tipo las estructuras son tridimensionales. Finalmente se han preparado análogos de nucleótidos tipo N1-alquiluracilos y de dinucleótidos tipo N1,N1'-polimetilen-bis-uracilos. / Bioinorganic chemistry deals with the study of the role of metal ions in biologic systems and the synthesis of model compounds to study more complex systems. In line with it, we have studied the interactions modes and recognition patterns that are present in ternary complexes of the type: metal ion - nucleobase - amino acid derivative. First of all, we have obtained a series of binary compounds with 5-halouracils and copper(II), zinc(II) and nickel(II) with a recognition pattern formed by a tandem of hydrogen bonds between uracils. With orto-iodohippuric acid, we have prepared some binary complexes with cobalt(II), nickel(II), copper(II), zinc(II) and silver(I). With these binary derivatives and acyclovir we have been capable to obtain ternary complexes were, the cobalt, nickel and zinc ones are isostructural and, due to the presence of a stacking between the acyclovir and one aromatic ring of o-iodohippuric acid, they generate in the crystal structure the two enantiomers δ (lower case delta) and λ (lower case lambda) if we consider the two ligands as a chelate by means of the stacking interaction. In the case of copper, we have prepared a series of ternary derivatives with different hippuric acids and 1,10-phenanthroline and 2,2'-bipyridyl. These complexes are capable to generate the copper(I) species [Cu(phen)2]+ and they present anticancer activity against A549 cell line. An important fact in all the coordination compounds with hippuric acids is that the presence of the aromatic ring normal to the amide bond promotes the formation of bi-dimensional structures, whereas with planar ligands of the same kind we obtain tri-dimensional structures. Last but not least, we have prepared nucleotide (N1-alkiluracils) and dinucleotide (N1,N1'-polymethilen-bis-uracils) type ligands.
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