Results 131 to 140 of about 86,596 (332)

Carboxylation of acetonyldethio‐coenzyme a by acetyl coenzyme a carboxylase

FEBS Letters, 1978
Charles J. Stewart, Tetsuo Shiba, Shosaku Numa, Jun-ichi Nikawa, Theodor Wieland   +4 more
openaire   +3 more sources

Structural and Spectroscopic Insights into Catalytic Intermediates of a [NiFe]‐hydrogenase from Group 3

ChemBioChem, EarlyView.
Hydrogenases catalyze reversible H2 production and are potential models for renewable energy catalysts. Here, the full redox landscape of a group 3 [NiFe]‐hydrogenase from methanothermococcus thermolithotrophicus is elucidated, resembling group 1 enzymes.
Marion Jespersen, Christian Lorent, Olivier N. Lemaire, Ingo Zebger, Tristan Wagner   +4 more
wiley   +1 more source

3α-Hydroxysteroids as Coenzymes of Hydrogen Transfer between Di- and Triphosphopyridine Nucleotides

, 1958
Barbara Hurlock, Paul Talalay
openalex   +1 more source

Cobalamin‐Dependent Aryl Methyl Ether O‐Demethylases: Promising Enzymes for Biocatalytic Applications from Lignin Valorization to Organic Synthesis

ChemCatChem, EarlyView.
Cobalamin‐dependent aryl methyl ether O‐demethylases have high potential for biocatalytic applications, including lignin valorization and synthetic chemistry. In this review, we provide a detailed overview of such O‐demethylase systems identified to date from various microorganisms, including their mechanism, substrate scope and selectivity, and ...
Niels Krabbe Johnsen, Santipap Chaiyasarn, Zheng Guo, Jaehong Han, Bekir Engin Eser   +4 more
wiley   +1 more source

On the Mechanism of Dehydrogenation of Fatty Acyl Derivatives of Coenzyme A

, 1958
Elizabeth P. Steyn-Parvé, Helmut Beinert   +1 more
openalex   +1 more source

Artificial Enzymatic Electrochemistry

ChemElectroChem, EarlyView.
Artificial enzymatic electrochemistry has emerged as an effective method to extend the catalytic abilities of enzymes. This review explores the bioelectrochemical methods used to understand and optimize the structure and function of artificial enzymes.
Nya E. Black, Dara Cheng, Brandon P. Grasty, Dylan G. Boucher   +3 more
wiley   +1 more source

Can the origin of biosynthetic routes be explained by a Frankenstein's monster-like spontaneous assembly of prebiotic reactants? [PDF]

Philos Trans R Soc Lond B Biol Sci
Negrón-Mendoza A, Hernández-Morales R, Lazcano A.   +2 more
europepmc   +1 more source

CARBON DIOXIDE, COCARBOXYLASE, CITROVORUM FACTOR, AND COENZYME A AS ESSENTIAL GROWTH FACTORS FOR A SAPROPHYTIC TREPONEME (S-69)

, 1954
Harry G. Steinman, Vance I. Oyama, Henry O. Schulze   +2 more
openalex   +1 more source

B12‐Cofactor Inactivation by Cobalt to Rhodium Mutation in Methylrhodibalamin: An Antivitamin B12 and Antibiotic

ChemistryEurope, EarlyView.
Replacement of cobalt in the organometallic B12‐cofactor methylcobalamin (MeCbl) by rhodium furnishes a structural mimic with a significantly stronger metal–carbon bond. This synthetically challenging formal metal‐mutation converts the naturally optimized biological methyl‐transfer catalyst MeCbl into a designed antivitamin B12, an inactivated B12 ...
Florian J. Widner, Klaus Wurst, Markus Ruetz, Christoph Kieninger, Christoph Kreutz, Michael D. Paxhia, Evelyne Deery, Martin J. Warren, Bernhard Kräutler   +8 more
wiley   +1 more source

Editorial: Enzymes from Extreme Environments

Frontiers in Bioengineering and Biotechnology, 2016
Noha M. Mesbah, Felipe Andres Sarmiento
doaj   +1 more source