Biochemical and Structural Analysis of the Thermostable Orotidine 5'-Monophosphate Decarboxylase from the Archaeon Sulfolobus Acidocaldarius

Craig, Michael P.

08 November 2001

No description available.

Sulfolobus Acidocaldarius

Orotidine

Decarboxylase

Archaea

Disulfide

Synthesis of rare nucleobases and artificial nucleotides for investigation of catalytic enzyme activity

Krull, Matthias

25 September 2019

No description available.

540

Chemie  (PPN62138352X)

Challenges in Enzyme Catalysis - Photosystem II and Orotidine Decarboxylase : A Density Functional Theory Treatment

Lundberg, Marcus

January 2005

<p>Possibly the most fascinating biochemical mechanism remaining to be solved is the formation of oxygen from water in photosystem II. This is a critical part of the photosynthetic reaction that makes solar energy accessible to living organisms.</p><p>The present thesis uses quantum chemistry, more specifically the density functional B3LYP, to investigate a mechanism where an oxyl radical bound to manganese is the active species in O-O bond formation. Benchmark calculations on manganese systems confirm that B3LYP can be expected to give accurate results. The effect of the self-interaction error is shown to be limited. Studies of synthetic manganese complexes support the idea of a radical mechanism. A manganese complex with an oxyl radical is active in oxygen formation while manganese-oxo complexes remain inactive. Formation of the O-O bond requires a spin transition but there should be no effect on the rate. Spin transitions are also required in many short-range electron-transfer reactions.</p><p>Investigations of the superproficient enzyme orotidine decarboxylase support a mechanism that involves an invariant network of charged amino acids, acting together with at least two mobile water molecules.</p>

photosystem II

oxyl radical

manganese systems

orotidine decarboxylase

reaction mechanism

density functional theory

Quantum chemistry

Kvantkemi

Challenges in Enzyme Catalysis - Photosystem II and Orotidine Decarboxylase : A Density Functional Theory Treatment

Lundberg, Marcus

January 2005

Possibly the most fascinating biochemical mechanism remaining to be solved is the formation of oxygen from water in photosystem II. This is a critical part of the photosynthetic reaction that makes solar energy accessible to living organisms. The present thesis uses quantum chemistry, more specifically the density functional B3LYP, to investigate a mechanism where an oxyl radical bound to manganese is the active species in O-O bond formation. Benchmark calculations on manganese systems confirm that B3LYP can be expected to give accurate results. The effect of the self-interaction error is shown to be limited. Studies of synthetic manganese complexes support the idea of a radical mechanism. A manganese complex with an oxyl radical is active in oxygen formation while manganese-oxo complexes remain inactive. Formation of the O-O bond requires a spin transition but there should be no effect on the rate. Spin transitions are also required in many short-range electron-transfer reactions. Investigations of the superproficient enzyme orotidine decarboxylase support a mechanism that involves an invariant network of charged amino acids, acting together with at least two mobile water molecules.

photosystem II

oxyl radical

manganese systems

orotidine decarboxylase

reaction mechanism

density functional theory

Quantum chemistry

Kvantkemi

Reaction mechanism of hOMPD and CaAAD at atomic resolution

Rindfleisch, Sören

07 February 2019

No description available.

572

Orotidine 5'-monophosphate decarboxylase

Acetoacetate decarboxylase

Catalysis

Decarboxylation

Transition-state stabilization

Ground-state destabilization

Biologie (PPN619462639)