BIOCATALYSIS BY NOVEL METAL CLUSTERS AND HYDROGENASE (STRUCTURE REACTIVITY AND IMMOBILIZATION)

Cel

PROTEINS CONTAINING METAL IONS DO CATALYSE MANY IMPORTANT BIOLOGICAL REACTIONS, NAMELY THOSE INVOLVING TRANSFER OF ELECTRONS. IT IS ANTICIPATED THAT MODIFICATIONS OF THE METAL CLUSTERS OF THESE PROTEINS WILL OPEN NEW CATALYTIC POSSIBILITIES THAT CAN BE USED IN MULTIPHASE BIOCATALYSIS AND THE DEVELOPMENT OF NOVEL BIOREACTORS. THE DESIGN OF SUCH CATALYSTS OBTAINED BY A BIOSYNTHETIC ROUTE MAY TURN OUT TO BE ADVANTAGEOUS IN COMPARISON WITH CHEMICAL SYNTHETIC ONES AND CAN THUS SUBSTANTIALLY EXPAND THE FIELD OF BIOINORGANIC CHEMISTRY.
Iron sulphur proteins are involved as main catalysts in bioconversion processes (hydrogen evolution, nitrogen and carbon monoxide fixation, photosynthesis, respiration, etc). The metal active centres of different iron sulphur proteins (simple and complex, eg rubredoxin, ferredoxins and hydrogenase) were characterised and chemically modified, in order to produce new active structures with novel, and/or enhanced catalytic properties. A new concept of assisted inorganic synthesis by a protein template was developed for the synthesis of mixed metal clusters. The reactivity and stability of the newly formed catalysts and hydrogenase (free and immobilised) were tested by measuring hydrogen evolution/production, deuterium(2)/hydrogen(+) exchange (mass spectrometry) and hydrogenation activity. Another important goal was to develop an adequate system to test hydrogenation activity in a multiphase biocatalyst system with immobilised hydrogenase or bacterial cells.

Iron sulfur proteins are involved as main catalysts in bioconversion processes (hydrogen evolution, nitrogen and carbon monoxide fixation, photosynthesis, respiration, etc). The metal active centres of different iron sulfur proteins, simple and complex, (eg, rubredoxin, ferredoxins and hydrogenase) were characterized and chemically modified, in order to produce new active structures with novel, and/or enhanced catalytic properties. A new concept of assisted inorganic synthesis by a protein template was developed for the synthesis of mixed metal clusters. The reactivity and stability of the newly formed catalysts and hydrogenase (free and immobilized) were tested by measuring hydrogen evolution and production, deuterium protium exchange (mass spectroscopy) and hydrogenation activity.

The following results were obtained (from research into the structure, reactivity and immobilization of metalloproteins:
isomorphous substitutions (cobalt and nickel) of the iron centre in rubredoxins:
chemical and spectroscopic characterization;
testing biocatalytic performance and mimicking of bacterial hydrogenase activity (model design);
assisted inorganic synthesis of novel mixed metal clusters of the type M, 3 iron-4 sulphur (M = cobalt, nickel, zinc, cadmium, calcium);
spectroscopic studies involving electron paramagnetic resonance (EPR), nuclear magnetic resonance (NMR) and Moessbauer methods;
characterization of the metal sites involved in bacterial hydrogen production and consumption;
differentiation of hydrogenase types by their spectroscopic, catalytic and inhibition parameters;
biocatalysis in organic media using hydrogenase encapsulated in micellar systems;
kinetics of both free and immobilized hydrogenases;
stability of the hydrogen evolving system in reversed micellar systems (multiphase system) using purified hydrogenase and whole cells.
THE RESEARCH WILL DEAL WITH TWO ASPECTS : IMMOBILIZATION PROCEDURES AND MULTIPHASE BIOCATALYSIS. METALLOPROTEINS WITH A MODIFIED METAL CLUSTER, AS OBTAINED BY THE GROUP OF DR MOURA IN THIS PROJECT, WILL BE IMMOBILIZED BY THE FOLLOWING METHODS : COVALENT LINKAGE TO A POROUS SILICA SUPPORT OR MICROENCAPSULATION IN REVERSED MICELLES. THE EFFECT OF THIS IMMOBILIZATION ON THE RETENTION OF THE ENZYMATIC ACTIVITY AND THE OPERATION STABILITY OF THESE ENZYMES WILL BE STUDIED. IN A MODEL SYSTEM, WITH ACETYLENE GAS AS A SUBSTRATE, HYDROGENATION REACTIONS WILL BE STUDIED IN A MULTIPHASE SYSTEM ULTIMATELY LEADING TO THE DESIGN OF A MULTIPHASE BIOREACTOR.

Dziedzina nauki (EuroSciVoc)

Klasyfikacja projektów w serwisie CORDIS opiera się na wielojęzycznej taksonomii EuroSciVoc, obejmującej wszystkie dziedziny nauki, w oparciu o półautomatyczny proces bazujący na technikach przetwarzania języka naturalnego. Więcej informacji: Europejski Słownik Naukowy.

• nauki przyrodnicze nauki chemiczne chemia nieorganiczna chemia bionieorganiczna
• nauki przyrodnicze nauki chemiczne chemia nieorganiczna związki nieorganiczne
• nauki przyrodnicze nauki chemiczne chemia nieorganiczna metale przejściowe
• nauki przyrodnicze nauki chemiczne kataliza biokataliza
• nauki przyrodnicze nauki biologiczne biochemia biocząsteczki białka enzymy

Program(-y)

Wieloletnie programy finansowania, które określają priorytety Unii Europejskiej w obszarach badań naukowych i innowacji.

• FP1-BAP - Multiannual research action programme (EEC) in the field of biotechnology (BAP), 1985-1989

Temat(-y)

Zaproszenia do składania wniosków dzielą się na tematy. Każdy temat określa wybrany obszar lub wybrane zagadnienie, których powinny dotyczyć wnioski składane przez wnioskodawców. Opis tematu obejmuje jego szczegółowy zakres i oczekiwane oddziaływanie finansowanego projektu.

Zaproszenie do składania wniosków

Procedura zapraszania wnioskodawców do składania wniosków projektowych w celu uzyskania finansowania ze środków Unii Europejskiej.

System finansowania

Program finansowania (lub „rodzaj działania”) realizowany w ramach programu o wspólnych cechach. Określa zakres finansowania, stawkę zwrotu kosztów, szczegółowe kryteria oceny kwalifikowalności kosztów w celu ich finansowania oraz stosowanie uproszczonych form rozliczania kosztów, takich jak rozliczanie ryczałtowe.

CSC - Cost-sharing contracts

Koordynator

Uczestnicy (2)